Abstract
Evidences from fossil records and genetic research suggest that the arboreal refugia were not restricted to Southern Europe and in particular to the Mediterranean peninsulas during the full-glacials. Fossil pollen data and macrofossil remains indicate that several tree species have survived also at the Southern edge of the cold-dry steppe-tundra area in Central and Eastern Europe. Recent results of surveys on the Late Pleistocene Mammalian fauna clearly contradict to the “tree-less tundra” models for Europe North of the transverse mountain ranges of the Pyrenees, Alps and Carpathians. It was pointed out that the carrying capacity to feed the herds of large herbivores demands a rather productive environment. The presence of Northern temperate refugia is also supported by the “non-analogue” assemblages of small mammals discovered from the Late Pleistocene of unglaciated areas of Eastern Central Europe. The assembly of species today typifying the tundra, steppe and semi-desert habitats seems to include also species from deciduous woodland. Extra-Mediterranean core areas were identified also in widely dispersed cold-tolerant frogs and reptiles. Some of their core areas had been at least near the Carpathians and/or marginal areas of the Carpathian Basin. The close faunal connections of the Carpathians suggest the existence of highly dynamic contacts and exchanges with mountains of the Balkan Peninsula during the climatic fluctuations of the Upper Pleistocene. The Eastern and Southern Carpathians, together with the mountains of Western Transylvania, can be considered as core areas of survival and autochtonous evolution in some invertebrate groups with limited mobility. The post-glacial re-population of the Carpathian Basin from different directions has been supported by Illyrian versus Dacian vicarious pairs of sister species/subspecies. In mobile insect groups, peripherically isolated sibling species/subspecies have only been evolved, which display manifold biogeographic connections, e.g. to the Balkan Peninsula, Asia Minor or Southern Russia. The organisation of community-complexes of the Pannonian forest-steppe connected by habitat ecotones resulted in the overlap of several different faunal types, e.g. Mediterranean, Balkanic, Siberian, Ponto-Caspian, Ponto-Pannonian, Turano-Eremic and Xeromontane elements.
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1 Introduction: Refugia and Core Areas of Dispersal
1.1 The Basic Components of the European Fauna
Traditional biogeography has been loaded with a seemingly endless discussion on the principles and methods of the biogeographical characterisation of species. In the geobotanical literature, the purely chronological (geoelements) and the historical approaches (geno-, migro- and chrono-elements) have regularly been clearly disentangled (e.g. Walter and Straka 1970). In the zoogeographical literature, the term “faunal element” or “faunal type” has repeatedly been used for both approaches, often with a mixture of points of view. Faunal types have often been differentiated on the basis of the shape and the extension of the ranges (e.g. the “Central European”, “Palearctic” or “Holarctic”, etc. faunal elements in many faunistical publications). Quantitative methods of biogeography based on large databases have only rarely been used. Dennis et al. (1991) differentiated some types of endemic versus “extent” (i.e. widespread) species of butterflies, and have outlined some “faunal structures”, based on multivariate methods. As opposed to these methods, the European fauna has traditionally been subdivided into a “holothermic” refugial and a “holopsychric” invasion types (Rebel 1931). In addition, these faunal types have been characterised by some “core areas” (in German: Arealkerne, chorologische Zentren: Reinig 1950; de Lattin 1957, 1967) and interpreted as areas of survival (refugia) and, consequently, as “centres of dispersal” (“Ausbreitungszentren” in the German tradition).
The “holothermic” type was differentiated according to the secondary subdivision of the large Mediterranean refugial area (de Lattin 1949, 1957, 1967; Reinig 1950). Recently, this view was strongly confirmed and modulated by the growing molecular results and re-formulated as repetitive patterns of the generalised “paradigms” of core areas and tracks of post-glacial re-population. A general conclusion was that temperate species mainly derive from Mediterranean refugial populations that underwent range expansion in the late glacial and early post-glacial periods (Hewitt 1996, 1999, 2000, 2001, 2004; Taberlet et al. 1998; Schmitt and Hewitt 2004; Schmitt 2007). The other main group, the “holopsychric” type has been considered for a long time as a result of the “Siberian” invasion, suggested by some “classical”, monoglacialistic biogeographical works (Hofmann 1873; Scharff 1899) and despite the evidences which have revealed the taxonomical differentiation of North-Eastern “boreal” and Southern European montane populations, especially in some butterfly species (Varga 1975, 1977; Nève 1996). Several authors (e.g. Schmitt and Seitz 2001; Steward and Lister 2001; Surget-Groba et al. 2001; Babik et al. 2004; Ursenbacher et al. 2006; Saarma et al. 2007), however, have suggested an additional mode of colonisation of central and Northern Europe by non-Mediterranean populations, coming from one or more “continental” refugia: central Europe, Southern Ural, Caucasus and Western Asia. Other species exhibit mixed patterns, where different parts of Europe have been colonised both from Mediterranean and/or non-Mediterranean refugia (e.g. Fumagalli et al. 1996; Deffontaine et al. 2005; Kotlík et al. 2006).
1.2 The Geographical Projection of the Faunal Type Frequency Data
The faunal composition of formerly glaciated and therefore, nearly exclusively post-glacially re-populated Northern Europe is practically identical with North-Eastern Europe and Western Siberia which were considered as a main argument for being re-populated mostly from the East (Rebel 1931; de Lattin 1957, 1967). This major part of Europe clearly shows a high percentage of the “Siberian” faunal type in all mobile groups of animals such as birds (Stegmann 1932, 1938; Voous 1960, 1963) and butterflies (Reinig 1950; de Lattin 1964, 1967, see: Fig. 59, in Kostrowicki 1969; Fig. 1). This faunal type is also strongly represented in Central Europe, North of the Alps, being the prevailing faunal type mostly in the mountainous regions (e.g. Harz Mts., Bavarian and Bohemian forest, Sudetic Mts., etc.). In contrast, South of the large transversal chains of the Pyrenées, the Alps and the Northern Carpathians, the pre-dominance of the Mediterranean faunal type sensu lato has been demonstrated, with a decreasing gradient into Northern direction being extremely steep at the Pyrenees and partly North of the Alps and the Carpathians, but much more gently sloping from the Balkan peninsula to the Carpathian Basin. As a consequence of the overlapping of the different biogeographical influences, there is a transitional belt in Southern Central Europe including a large part of the Carpathian Basin where the proportions of the different faunal types are rather balanced (de Lattin 1967; Varga and Gyulai 1978; Varga 1995, 2003b, 2006).
Several consequences follow from this general biogeographical setting of Europe.
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In Europe, the highest number of endemic species is confined to some, mostly mountainous parts of the Mediterranean peninsulas (e.g. Williams et al. 1999; Finnie et al. 2007). These areas, more or less, regularly overlap in the different taxonomical groups; thus they can be considered as hotspots for endemism, and at the same time, they were the main areas of survival during the Quaternary glaciations. These areas often show also a high level of “multi-species genetic divergence” (Petit et al. 2003).
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On the other hand, there are ecologically transitional regions with high numbers of species, but without a high proportion of endemism (Williams et al. 1999). These are characterised by an overlap of the ranges of species of different geographical origins caused by dispersal processes along gradients, e.g. the overlap of species belonging to different zonobiomes and azonal communities in the forest-steppe areas of the Carpathian Basin (Varga 1995). Recently, these areas have been identified as “melting pots” of genetic diversity (Petit et al. 2003) due to the secondary accumulation, re-distribution and re-combination of genotypes.
Another important observation was made by de Lattin (1957, 1964) who indirectly defined the “Siberian” species by their absence in the supposed Mediterranean refugial areas. These species show a peculiar “crowding” (de Lattins’ “Stauungslinie”) at the Northern boundary of the Mediterranean region. The re-interpretation of this biogeographical line subsequently followed in two steps. First, it was recognised that accumulated occurrence of marginal sub-species of continental species was shown around this line (Varga 1975, 1977), and later on, they were confirmed as multiple extra-Mediterranean refugia of continental species (Schmitt 2007; Schmitt et al. 2007) (Fig. 1).
1.3 The Geographical Projection of the Genetic Diversity Data
It is not only the number of the species, but also some characteristics of the genetic diversity that show the highest values in the “transitional” belt mentioned above. Based on the chloroplast DNA variation in 22 widespread European trees and shrubs, it was pointed out that despite their “individualistic” migration behaviour, diverse ecological requirements (from the Southern temperate to the Southern boreal zone) and different modes of seed dispersal, significant species of the woody flora of Northern Central Europe exhibited an essentially congruent pattern of genetic divergence (Petit et al. 2003; Fig. 1). Their genetically most unique populations are found in Southern and central Italy, Corsica, and the Balkan Peninsula extending into Northern Italy, the Northern Balkans and the Southern peripheries of the Carpathian Basin. However, this increased diversity is obtained mostly through the redistribution (“melting pot”) of the genetic information already present in the populations in refugia (the actual “hot spots”, i.e. areas where the diversity was evolved). Recent work on the genetics of oak populations has revealed that the existence of particular haplotypes in Romania resulted either from older indigenous relict populations or from crossing of populations originating from more than one refugium. There were several low or medium mountains North of the Balkan Peninsula that could have offered favourable climatic conditions during the Younger Dryas period to support viable populations of oak trees. At the beginning of the post-glacial times, the Carpathian Basin may have acted as a meeting point of several colonisation routes (Bordács et al. 2002; Petit et al. 2002). These genetic data are also supported by recent fossil findings of tree remains from the last full glacial period, North of the Mediterranean peninsulas. Fossil pollen data and macrofossil remains such as charcoals from the time of the last glacial maximum, i.e. 25,000-17,000 years ago, indicate that several tree species remained in small favourable pockets not only within the Mediterranean region, but also at the Southern edge of the cold and dry steppe-tundra area in Eastern, central, and South-Western Europe (Willis et al. 1995, 2000; Carcaillet and Vernet 2001).
Research on small-mammal mtDNA has also questioned the universality of Mediterranean refugia as the areas from which all temperate taxa colonised central and Northern Europe at the beginning of the present interglacial period. It was suggested that the Mediterranean “sanctuaria” (Widmer and Lexer 2001) in general were not also core areas of post-glacial expansion into deglaciated areas. Thus, a need for new paradigms for the phylogeography of cold- resistant arboreal species has been formulated, as well (Steward and Lister 2001). It was shown that Mediterranean populations of the shrews Sorex minutus, Sorex araneus and bank voles (Chlethrionomys spp.) did not contribute to the present-day gene pools in Central Europe (Fumagalli et al. 1996; Bilton et al. 1998). Instead, populations in Central Europe and Western Asia have participated suggesting the existence of glacial refugia in these regions. The central European evidences fit well with the botanical results from Hungary and the records of temperate mammals within cold-stage assemblages of central and Northern Europe (Fig. 2).
2 The Basic Types of Zonal Setting in Europe: Glacial Vs. Interglacial
2.1 The Notion of the Boreal Forest-Steppe as the Macro-Ecotone of the Mammoth Steppe and the Boreal Forest
The Pleistocene glacial-interglacial cycles have resulted in the “antagonistic dynamics” of biota belonging to contrasting macrohabitats (de Lattin 1967, p. 356). Thus, principally, two basic types of zonal setting can be distinguished. The inter-/post-glacial (but also interstadial!) type can be characterised by the expansion of the Arboreal and regression of the “non-Arboreal” macrohabitats. As a result, the “open” macrohabitats (tundra, steppe, semi-desert and high mountains) have been separated by wooded zonobiomes, such as boreal and nemoral forests. Significant belts of macro-ecotones have been developed at the edges of the forested belts, e.g. forest-steppe as a transitional habitat type between the nemoral and steppic zones, subdivided into a sub-mediterranean (Pannonian) and a continental sub-type (Zólyomi 1949; Sjörs 1963; Walter and Straka 1970; Varga 1995; Fekete and Varga 2006).
Thus, the glacial periods (stadials) have been characterised by a regression plus fragmentation of wooded habitats and consequently, by a broad contact of the tundra and the steppe zonobiomes with some forested “pockets” North of the refugial belt of the Mediterranean area. The transitional “macro-ecotones” developed at the forest-belt fringes: tundra-taiga and boreal forest-steppe (e.g. in Pannonian region). Recently, cold steppe vegetation with scattered boreal coniferous forests have been revealed during the cold stages in S Moravia, the SE margin of the Alps, E Hungary, parts of Romania (Carpathians), etc. (Rybnicková and Rybnicek 1991; Willis et al. 2000; Pokorny and Jankovská, 2000; Sümegi and Rudner 2001; Wohlfahrt et al. 2001; Björkman et al. 2003; Tantau et al. 2003; Willis and Andel 2004; Feurdean et al. 2007a,b). The presence of these Northern temperate refugia justifies the arguments for the so-called non-analogue assemblages of mammals described from the Late Pleistocene in unglaciated areas of the Northern hemisphere.
The Würm glaciation had at least six maxima, the last one taking place about 22.000-18.000 years BP. The Last Glacial Maximum (LGM) was extremely continental and ended in rapid climatic fluctuations. The late Würm kryoxerotic period was characterised by the expansion of cold-continental heliophyta and steppic species (Iversen 1958; Tarasov et al. 2000; Velichko et al. 2002). Pollen-based “tree-less tundra” models for Europe North of the transverse mountain ranges of the Pyrenees, Alps and Carpathians (e.g. Frenzel 1992; Huntley and Birks 1983; Huntley and Allen 2003) have repeatedly been questioned by researchers of the late Pleistocene mammalian fauna (Kretzoi 1977; Guthrie 1990, 2000; Guthrie and van Kolfschoten 1999; Simakova 2001; Yurtsev 2001; Steward and Lister 2001), because the carrying capacity sufficient to feed numerous large herbivores such as the mammoth, the woolly rhinoceros, the reindeer, the giant deer, the bison or the auerochs demands a very productive environment (“steppe-tundra” or “mammoth steppe”, Guthrie 1990), like the cold-continental meadow steppes in Southern Siberia and Northern Mongolia (Varga et al. 1989).
Although the East-West faunal movements between the Western and Eastern temperate refugia (see: nemoral disjunctions!) were hindered during the last glaciation, the tundro-steppic areas of E Europe and the mountain belts of Central Asia were connected to each other. Thus, non-analogue communities were composed by mixing tundral, steppie and eremic-oreal elements (e.g. Lemmus and Dicrostonyx spp. together with Citellus spp. and Allactaga, Sicista, Lagurus, Marmota and Ochotona). This boreal forest-steppe habitat type appears to have included also cold-tolerant species of temperate habitats, e.g. Clethrionomys glareolus, Apodemus sylvaticus and S. araneus. Extra-Mediterranean core areas have also been revealed in several, widely dispersed cold-tolerant frogs and reptiles, as Rana arvalis, Zootoca vivipara, Vipera berus (Surget-Groba et al. 2001; Babik et al. 2004; Ursenbacher et al. 2006; Kotlík et al. 2006; Saarma et al. 2007).
3 European Refugia of Boreal Species
3.1 Biogeographical Definition and Sub-Division of Boreal Species
The species of the boreal zone show a significant diversity of extension and taxonomical structure of ranges. Most boreal taiga-species are widely distributed from the Far East across Siberia to Scandinavia, often without significant geographical variations. They are partly inhabitants of forests but are often connected with peat bogs, e.g. due to the food-plant specialisation (e.g. the butterflies and moths Colias palaeno, Boloria aquilonaris, Plebejus optilete, Anarta cordigera, Arichanna melanaria). Vicarious taxa often occur in Southern Himalayan coniferous forests with dense scrub layer and undergrowth, rich in evergreen plant species (e.g. Rhododendron, Vaccinium spp.). Also, some boreal plant species complexes have a huge Holarctic or Eurasiatic range while their closest relatives are restricted to some Southern mountainous areas, as parts of the Himalaya, Tibet, etc., e.g. the boreal species complex consisting of the circum-boreal Saxifraga hirculus and the related spot-like Central Asiatic species: S. diversifolia, S. przewalskii and further species in Tibet. In other cases, the zonal boreal “taiga” distribution is combined with considerable disjunct ranges in the sub-alpine mixed coniferous forests of the Himalayas (e.g. several small passerine birds as Dumeticola thoracica, Luscinia calliope, Muscicapa sibirica, Phylloscopus proregulus, Tarsiger cyanurus) and/or with several larger or smaller spots in the European mountain coniferous belts, e.g. in many taiga-inhabiting birds, as Tetrao urogallus, Tetrastes bonasia, Strix uralensis, Aegolius funereus, Picoides tridactylus, etc. (Stegmann 1938; Voous 1963). Such species are most richly represented in the coniferous zone of the South Siberian high mountains.
The number of (nearly) exclusively European boreal and boreo-montane species is relatively low. However, a molecular biogeographical analysis of such species can unravel the European coniferous forest refugia (Schmitt and Haubrich 2008). The existence of European coniferous forest refugia is also supported by the Western-Eastern sub-division of several boreal species with the Western populations obviously having European refugia during the last glaciations, e.g. Picea abies most probably in the mountains of the Balkans and in the Eastern and Southern Carpathians. The North-Eastern part of European Russia was populated from the East by the sister (sub-)species Picea obovata. In the catchment area of the Northern Dvina, a hybrid belt has been formed between them. The European Pinus cembra survived the LGM in Southern Alpine and Carpathian refugia (Willis et al. 2000; Wohlfahrt et al. 2001). Its sister species is the SiberianNorthern Mongolian Pinus sibirica, a dominant species of the light-penetrated mountain taiga, often mixed with Larix sibirica (Walter and Breckle 1986).
3.2 Carpathian-Balkanic Boreo-Montane Arboreal Refugia
It is known since several decades that the Southern part of the Carpathian Mts. was a refugial area for temperate and mountain forest taxa during the last glacial period (Huntley and Birks 1983). The Eastern and the Southern Carpathians have been repeatedly pointed out as important glacial refugia, from which trees started to expand at the beginning of the Holocene (e.g. Huntley and Birks 1983; Bennett et al. 1991; Willis 1994). In particular, Willis et al. (2000) indicated that temperate refugia in Europe during cold periods might not have been restricted to the three Southern peninsulas (Iberia, Italy and the Balkans) because trees were undoubtedly present in Central Europe in areas such as the Carpathian Basin during the last cold stage. Radiocarbon data indicate the continuous presence of coniferous woodland not only during the relatively mild period from 35 to 25 kyr BP (thousands of radiocarbon years before the present), but also into the more severe last glacial maximum 25-17 kyr BP (Sümegi and Rudner 2001; Willis and Andel 2004).
The existence of full-glacial forests in Eastern Europe during the LGM (Willis et al. 2000) has often been questioned, but it has also been repeatedly confirmed by several macrofossil and palynological studies from the Carpathians (e.g. Farcaş et al. 1999; Björkman et al. 2003; Tantau et al. 2003; Willis and Andel 2004; Feurdean et al. 2007a) demonstrating the survival of most coniferous and cold-resistant deciduous trees or even the beech (Magri et al. 2006, Magri 2007) in refugial “pockets” in the hilly areas of the Carpathians or North of them. Similarly, forest refugia were also found in Southern Moravia, in the Eastern Alps, in the Dinaric Mountains and in the Eastern Balkans, etc. (Willis 1994; Willis and Niklas 2004). The climatic conditions in some favourable localities of these regions could not have been as severe as those in Northern and central Europe during the LGM and during the beginning of the last deglaciation.
In the NE Carpathians (Mt Gutaiului), Pinus mugo, P. sylvestris and later on also Larix became established from 14,500 year BP onwards (Wohlfahrt et al. 2001; Björkman et al. 2003). Between 14,150 and 13,950 years BP, P. cembra have replaced P. mugo and P. sylvestris. At 13,950 cal year BP, the tree cover increased and Picea appeared for the first time, together with P. cembra, P. mugo and Larix decidua. The analysis of the sediments of the peat bog “Mohos” in the Eastern Carpathians (Tantau et al. 2003) has shown that an open boreal forest was dominated by Pinus during the last phase of the LGM. The presence of Picea pollen refers to its existence in a local refugium. The pollen data at the end of the late Weichsel indicate that beside the dominant Pinus and Betula species, Alnus, Ulmus and Picea also occurred in the area. The increased representation of Alnus at about 14,150 year BP and that of Picea and Ulmus between 13,750 and 13,200 years BP is interpreted as a consequence of nearby refugia of these trees. Beech pollen was dated in the North- Eastern Carpathians (Semenic Mts.) to 9,500 year BP while in most other diagrams for the Romanian Carpathians, it was registered between 7,500 and 8,000 years BP. From the late expansion of Quercus, Tilia, Fraxinus, Acer and Corylus between 10,750 and 10,200 years BP, it was concluded that these trees had to immigrate into the area from refugia further away. However, these refugia cannot have been situated very far from the Carpathians. It seems most likely that these refugia were located further to the South in Romania, or in lower hilly areas of the Carpathian Basin (Feurdean et al. 2007b). Several surveys across Hungary (Rudner and Sümegi 2001; Willis et al. 2001) from about 30 sites clearly demonstrate that cyclically recurring forested habitat developed in the Carpathian Basin during the late Weichselian, although this forest type might have been of an open forest or steppe forest/forest-steppe type. These forests or forest-steppes were of the boreal type mostly with cold-tolerant trees as Picea, Larix, Pinus sylvestris and P. cembra, Betula, Carpinus, Salix and Juniperus communis.
In Bátorliget, North-Eastern Hungary, a light-penetrated taiga forest and a cold steppe with Artemisia spp. dominated during the last cold phase of the Weichselian glaciation. However, it has also been demonstrated that some deciduous trees such as Quercus, Ulmus, Alnus and Tilia survived in meso/microclimatically favourable “pockets” of this mosaic landscape (Willis et al. 1995). Later, Tilia dominated woodland and a mixture of deciduous trees including Ulmus, Corylus, Tilia, Fraxinus and coniferous species (Pinus and Picea) (Willis et al. 1995, 2000; Magyari et al. 1999) were present in the early Holocene. In a neighbouring area of Romania (Turbuta), pollen of Quercus was not found before 12,000 year BP implying that Quercus did not survive in the proximity of the study site during the late glacial. Local stands of Quercus pollen became established between 12,000 and 11,000 years BP, but its local expansion did not occur until about 11,000 cal year BP and peaked between 10,000 and 8,500 years BP. This is generally simultaneous with the time of Quercus expansion in North-Western, Western and South-Western Romania, though in the Eastern Carpathians its expansion was dated to ca. 500 years later (Farcaş et al. 1999, 2004; Björkman et al. 2003; Tantau et al. 2003, 2006; Feurdean and Bennike 2004; Feurdean et al. 2007a).
The fossil and genetic data unanimously indicate that the beech (Fagus sylvatica) also survived the last glacial period in multiple refuge areas. Recent publications (Magri et al. 2006; Magri 2007) clearly demonstrate that the central European refugia of the beech were separated from the Mediterranean ones. In addition, the Mediterranean core areas did not contribute to the colonisation of central and Northern Europe. The Illyrian-Slovenian population migrated only to a limited extent Northward to colonise the rest of Europe. This population proved to be genetically similar to the population in Southern Moravia-Southern Bohemia, which is considered to be a possible refuge area on the basis of fossil data. This core area might have been the source for the colonisation of the Carpathians. From a genetic point of view, the populations in the Apuseni Mts. have been characterised by rather high allelic richness (Gömöry et al. 2003). Thus, it is possible that a secondary refugium of the beech was located in this area, which, however, did not significantly contribute to the colonisation of the Carpathian arc.
3.3 Refugia of Cold-Tolerant Invertebrates and Exothermic Vertebrates in Eastern Central Europe
Vertebrate and Mollusc remains show that the lowest Weichselian loess layers in the Carpathian Basin were formed during the first cool/dry phase of the last glacial, between 50,000 and 70,000 years BP (Hertelendy et al. 1992). The dominance of woodland species decreased, but the tree cover was able to survive the unfavourable environmental changes because, as a result of the mosaic-like environment, some mild and humid micro-climatic areas developed in the foothill zone. On the Tokaj hill, for example, a coniferous forest-steppe was revealed with wildfires in a taiga-like environment during the LGM. Charcoal from Picea and podsolic soils were identified (Sümegi and Rudner 2001).
Between 22,000 and 20,000 years BP, a decline of thermophilous gastropod species and expansion of a kryo-xerophilous, xeromontane element were observed (Sümegi and Krolopp 2002; Füköh et al. 1995). The occurrence of Vallonia tenuilabris was shown together with the boreo-Alpine/montane Columella columella. The dominance of the kryophilous land snails reached values of 80% in the Northern parts of the Carpathian Basin while the occurrence of the same group was about 40% in the Southern parts. Data of mollusc analysis refer to a large-scale heterogeneity in both palaeogeographic and palaeobiogeographic conditions for the area examined, creating some sort of a meeting point of faunal elements adapted to different environmental conditions in the region. The “gastropod-thermometer” developed by Krolopp and Sümegi (1995) showed a mean July temperature about 11-12°C in the Northern and 13-14°C in the Southern part of the basin during the LGM. Several further land snails and slugs (Arianta arbustorum, Trochoidea geyeri, Arion fuscus and Arion spp.) were also able to survive harsh climatic conditions in small spots in the central European periglacial (Haase et al. 2003; Pinceel et al. 2005) or even within the Alpine permafrost area. DNA and allozyme data on A. fuscus show that its glacial survival was possible in or at the periphery of the Alps as well as in other European mountain ranges (e.g. the Tatra Mountains and Southern Balkans).
In the group of continental species, the woodland ringlet (E. medusa) represents a particularly interesting and well-studied case. Good evidences have been found based on allozyme data that this specie had multiple Würm ice-age differentiation centres around the glaciated Alps, in the Carpathian region and in the Balkan Peninsula (Schmitt and Seitz 2001; Schmitt et al. 2007). This glacial distribution pattern of E. medusa shows several parallel features with cold-tolerant vertebrates such as the adder, the bank vole, etc. (Deffontaine et al. 2005; Kotlík et al. 2006; Ursenbacher et al. 2006), most probably due to the particular climatic conditions of Eastern Europe during the last ice-ages. Supposedly, the decline of the temperature was, especially in the summer period, less dramatic as in the Atlantic part of Europe. This was combined with a decrease in the precipitation causing a transitional climate and mosaic-like vegetation similar to the recent conditions in the cold-continental forest-steppe belts of Southern Siberia and Northern Mongolia. Three of the four groups of E. medusa confined to the Carpathians most probably had their differentiation centres at the low elevations of the Southern-South-eastern Carpathians. The fourth lineage, composed of populations from the Western Carpathians and the North-Eastern Carpathians, might have had a core area of larger extent near to the Northern Carpathians or in the Carpathian Basin. The genetic diversity values of these populations suggest that the differentiation centre in the Carpathian Basin was as large and stable as the ones in the Southern Carpathians (Schmitt et al. 2007). Evidence for Central European refugia was also found for several other woodland species (Steward and Lister 2001). Recently, Schmitt and Haubrich (2008) indicated several Eastern European refugia of the large ringlet (Erebia euryale), a butterfly species strictly restricted to the European mountain coniferous forest zone. They concluded that the mountains of South-Eastern Europe were the most important reservoirs of the coniferous forests in Europe.
The Pleistocene glacial refugia of the European Bombina toads were located both in the “classical” refugial areas of the Appenins and the Balkans (core areas of B. pachypus and sub-species of B. variegata, Szymura et al. 2000; Canestrelli et al. 2006) as well as more to the North, in the Carpathians and the adjoining lowlands (Vörös et al. 2006; Hofman et al. 2007). Strong genetic evidences have been provided that B. variegata survived the LGM in the Carpathians. The mtDNA and allozyme data suggest two separate refugia. One clade probably had its refugium in the Southeastern edge of the Carpathians while the most likely refugium of the other clade was in the Southern Carpathians, where the haplotype diversity is the highest. However, the deep genetic divergence among European Bombina lineages suggests their pre-glacial origin.
The European populations of the moor frog are subdivided into three genetic lineages from which two are exclusively found in the Carpathian Basin. They, most probably, survived the LGM in the Carpathian Basin and have expanded to the North to a rather limited extent only (Babik et al. 2004). The survival of R. arvalis in the Carpathian Basin was also demonstrated with fossil records (Venczel 1997). This view is supported by further recent data suggesting that this region might have been an important LGM refugial area in other amphibians and reptiles, as well. In the lizard Z. vivipara, a haplotype restricted to Northern Hungary and Austria was found in a species-wide survey of mtDNA variation (Surget-Groba et al. 2001). This ovoviviparous form shows peculiar karyotypic characters and demonstrates that the ovovivipary independently evolved in the Western European and Pannonian (Z. vivipara pannonica) populations (Kupriyanova et al. 2006; Surget-Groba et al. 2006). The suggested refugia of the adder (V. berus) would be in the Southern pre-Alpine lowland (Italian clade), in the “Illyrian” core area in the Western Balkan peninsula (Balkanic clade) and several core areas of the Northern clade: in the Carpathian region (Carpathian sub-clade), East of the Carpathians (Eastern subclades) and in a location between Great Britain and Poland (Central European subclade). The survival of two mitochondrial lineages in the Carpathian Basin throughout the LGM was postulated in this species, one East of the Alps, and the other in the North-Eastern part of the basin or even in the Eastern Carpathians (Carlsson 2003; Ursenbacher et al. 2006).
3.4 Refugia of Boreal Birds and Mammals in Eastern Central Europe
Comparison of phylogeographic structures in several Eurasiatic boreal species has shown that species associated with the taiga forest revealed essentially similar patterns. In the wood lemming (Myopus schisticolor), and also in most other boreal forest species, no substantial phylogeographic divisions across Northern Eurasia have been reported (Zink et al. 2002; Fedorov et al. 2008). The contraction of the range of these species to a single, probably Southern Siberian refugial area during the late Pleistocene followed by demographic expansion seems to be a general background for their shallow phylogeographic structure. The most important genetic discontinuity has usually been observed between the “ Northern” Eurasiatic and the “Far East” clades. The limited distribution range of the South-eastern lineages suggests that their core areas (“Manchurian refugium” of de Lattin 1967) could not play an essential role in the post-glacial colonisation of Northern Eurasia by boreal forest species. A weak phylogeographic structure was also discovered in the flying squirrel (Pteromys volans), in which the divergence between the Far Eastern and Northern Eurasian groups may have been initiated during the Weichselian glaciation (Oshida et al. 2005). Mountain ranges in Southern Siberia and North-Eastern China may have isolated the Far Eastern group. Although the largest part of North-Eastern Europe and Siberia was not covered with ice during the last glaciation, most parts were overgrown by cold tundra-steppe (“mammoth steppe”) under extremely cold and dry conditions (Svendsen et al. 1999, 2004; Simakova 2001; Schirrmeister et al. 2002). At that time, multiple isolated refugia of P. volans could be formed in Eurasia. After the last glaciation, P. volans might have expanded throughout Northern Eurasia, along both sides of the Ural mountains.
Other boreal species show clear phylogeographical structures with well-differentiated populations in the coniferous forest zone of the South European mountains. They belong to rather different taxonomical groups. The brown bear complex can be mentioned as a classical example, (e.g. Taberlet and Bouvet 1994; Valdiosera et al. 2007). The discovery of 18,000-year-old charcoal of yew (Taxus baccata) and Scots pine (P. sylvestris) in Western Slovakia (Litynska-Zajac 1995) indicates that the climatic conditions at the Western Carpathians might have been suitable for the brown bear. The Eastern Carpathians served also as a refuge area for brown bears during the last glacial phase. Nevertheless, recolonization from the Eastern Carpathian refuge appears to have been less effective compared to the migration that began from the North-Western Carpathian refuge. This recolonization pattern can be explained by the more Northern position of the North-Western Carpathians (leading edge).
Southern European montane refugia have also been revealed in the capercaillie (T. urogallus). It was suggested that the Southern European aquitanus lineage had expanded throughout Europe before the LGM, and the Eastern, urogallus lineage expanded in Asia and North-Eastern Europe. During the LGM, the two lineages were restricted into separate refugia (aquitanus: Iberia and Balkans, urogallus: Southern Siberia). During the post-glacial re-forestation, the urogallus lineage replaced aquitanus in Europe and forced them to the South-west into their refugia in the Pyrenees and Cantabrian Mts. (Duriez et al. 2007).
Different phylogeographical structures have been revealed in the root voles (Brunhoff et al. 2003), lemmings (Fedorov et al. 1999), collared lemmings (Fedorov and Stenseth 2002), and common voles (Haynes et al. 2003; Fink et al. 2004). In these cases, the Ural Mountains separated the Northern European and Siberian lineages. Root voles in Europe form a Northern and a central mtDNA phylogroup. Fossil records from the last glaciation have demonstrated that collared lemmings (Dicrostonyx) and true lemmings (Lemmus) used to be the most common small mammals in the periglacial tundro-steppe of central Europe. These species were regularly accompanied by several vole species, including the root vole. These species assembly always remained North of the “classical” Southern European refugia. Thus, central European root vole populations can be considered the sources of Northward expansion during the deglaciation. This model is corroborated by the data demonstrating that the fragmented populations in the Netherlands, Slovakia and Hungary all belong to a single mtDNA phylogroup. Consequently, the threatened populations in Hungary, Austria, Slovakia and the Netherlands represent glacial and post-glacial relicts (van de Zande et al. 2000).
Bilton et al. (1998) show that the Mediterranean populations of S. minutus, S. araneus and Clethrionomys spp. did not contribute to the present-day gene pools of the Central and Northern European populations. This view has also been supported by the high rate of endemism in the Mediterranean bank vole phylogroups. In contrast with some forest rodents (A. sylvaticus, A. flavicollis ), bank voles would not be restricted to the Southern forest refugia during the last glaciations. Therefore, bank vole populations might have survived the Quaternary glaciations in their Northern refugia. This may have resulted in their present complex phylogeographic pattern including multiple glacial refugia in central Europe, in the Mediterranean mountains and possibly also in several Eastern regions. Based on fossil records, the Carpathian region has been suggested as a glacial refugial area for this species. These refugia were most likely to be located near the Alps or in the Carpathians and possibly at the network of streams in the marginal areas of the Carpathian Basin. Phylogeographic analyses of the bank vole have already suggested that glacial refugia located in central and Eastern Europe made a major contribution to the modern population of this species in Europe (Deffontaine et al. 2005; Kotlík et al. 2006). The analysis of nucleotide diversity also demonstrates that these Eastern Central European regions acted as core areas of expansion for the Western lineage of the bank vole. Another refugial area was proposed in the regions of Eastern Romania, Western Azov Sea and the Crimea (Jaarola and Searle 2002).
4 Area Dynamics, Evolution and Diversity Patterns in the Carpathian Basin
4.1 Endemic Taxa and Autochtonous Evolution in the Carpathian Basin
The level of endemism generally correlates with the geological age of the refugia where relict-like taxa have been evolved and/or could survive. The Carpathian Basin belongs to the geologically young areas of Europe. Its relief developed under the influence of the Alpine orogenesis and by retreat of the Paratethys and the Pannonian inland sea. Moreover, the phylogeography of some freshwater invertebrates (e.g. Neritidae snails, see: Bunje 2007; Fehér et al. 2007) is clearly connected with the evolution of the Ponto-Pannonian water basin and of the Danube catchment area. In addition, there are several taxonomical groups with considerable proportion of endemic species, e.g. the land gastropods (Soós 1943) the earthworms (Lumbricidae: Csuzdi and Pop 2007) or some soil arthropods (e.g. Opiliones, Diplopoda: Korsós 1994; Collembola: Dányi and Traser 2007). Their core areas clearly coincide with the younger tertiary land masses within and near the Carpathian Basin.
Most endemic species are narrow specialists, inhabiting extreme habitats, such as thermal springs, karstic caves and karstic springs (Table 1). Several endemic troglobionta have been described in gastropods, pseudo-scorpions, harvestmen, spiders and springtails, often occurring within a single or a few caves of karstic mountains. Several species of earthworms, millipedes, centipedes and assels can be considered as holo-endemic species of the Western Transylvanian (Apuseni) mountains (Csuzdi and Pop 2007; Varga and Rakosy 2008).
Endemic terrestrial insects of the Carpathians are, as a rule, short-winged, flightless species such as the bush-crickets Isophya, Poecilimon spp.; some stenotopic relict grasshoppers (Capraiuscola ebneri, Podismopsis transsylvanica, Uvarovitettix transsylvanica, Zubovskia banatica; Kis 1965, 1980); numerous species of the ground beetles (Duvalius, Trechus, Patrobus, Morphocarabus spp.) and weevils (e.g. Otiorrhynchus spp.). A bulk of these endemic taxa is confined to the Eastern and Southern Carpathians, to the Apuseni Mts.and to the mountains of Banat, which could preserve relict species (e.g. the tertiary relict gastropods Chilostoma banaticum, Pomatias rivulare) or some narrow endemic species of Isopoda and Diplopoda (Table 2) in refugia without permafrost phenomena during the last glaciations (Bennett et al. 1991; Krolopp and Sümegi 1995; Willis et al. 1995).
In the more mobile insect groups, the proportion of endemism lies rather low (e.g. in Odonata no endemic taxa occur in the Carpathian Basin). Most endemic Lepidoptera of the Carpathian Basin belong to Microlepidoptera, which have flightless females and are strictly specialised to some food plants living on halophyta in the saline grasslands of the Fertő-Neusiedlersee area (Kasy 1965) and those of the Great Hungarian plain (Kiskunság and Hortobágy). Endemic subspecies of Geometridae and Noctuidae evolved as peripheric isolates of turano-eremic species from the late-glacial, kryoxerotic periods, e.g. Narraga tessularia kasyi, Saragossa porosa kenderesensis (on food plants: Artemisia santonicum, A. pontica) and Hadula dianthi hungarica (on Gypsophila muralis). Some endemic taxa in the sandy areas of the Pannonian lowland are specialised predators or parasitoids, e.g. the spider Dictyna szaboi and the pompilid wasp Cryptocheilus szabopatayi. Further species described as endemics later proved widely-dispersed steppicolous species. In their majority, the endemics of the lower, hilly parts of the Carpathian Basin, however, represent thermophilous post-(inter?-) glacial relicts with connections to the Balkan Peninsula, Asia Minor or Southern Russia (e.g. Apamea sicula tallosi in warm-humid alluvial areas, Dioszeghyana schmidtii schmidtii and Asteroscopus syriacus decipulae in Pannonian xerothermic oak forests, Polymixis rufocincta isolata in the Villányi Mts.; Chersotis fimbriola fimbriola, Euxoa vitta vitta, E. hastifera pomazensis and Cucullia mixta lorica in the dolomitic areas of the Transdanubian Middle Range, Chersotis fimbriola baloghi in the Aggtelek Karst). Balkanic connections have also been observed in butterfly species, which are restricted to special, Pontic-Pannonian steppic food plants, e.g. Plebeius sephirus (feeding on Astragalus exscapus, A. dasyanthus), Melitaea telona kovacsi (on Cirsium pannonicum).
Several endemic Macrolepidoptera subspecies of the Carpathians belong to the genera Erebia and Glacies (Table 3). A few endemic taxa are only widespread in the Carpathians and in the neighbouring mountainous areas, e.g. Aricia artaxerxes issekutzi, Photedes captiuncula delattini, while others are confined to the Southern Carpathians, often with Balkanic connections: Erebia cassioides neleus, Coenonympha rhodopensis schmidtii (Varga 1975, 2003a). The subspecies of Erebia melas inhabit island-like, calcareous mountain stocks, E. melas runcensis in the Apuseni Mts., E. melas melas in the Cernei Mts. and E. melas carpathicola in the Eastern Carpathians). All these data clearly demonstrate that the Carpathians, especially the Eastern and Southern parts, together with the mountains of Western Transylvania (Apuseni Mts. and Banat) can be considered as core areas for the survival and autochtonous evolution in many invertebrate groups of limited mobility.
4.2 The Carpathian-Balkanic Connections
The close geological and faunal connections of the Carpathians suggest the existence of highly dynamic contacts with the mountains of the Balkan Peninsula during the Upper Pleistocene. These connections show a contrasting picture compared to the refugia of the Iberian and the Appenine peninsula which have been much more sheltered by the glaciated mountains of the Pyrenées and the Alps, respectively. At least two major arboreal refugia can be traced here: the Illyrian refugium related to the Dinarids and its foothills and the Carpatho-Dacian refugium related to the Carpathians and its foothills. Some areas attached to these refuges served as periodic habitats over climatically favourable periods. These are regarded as fluctuation zones (Varga 1995; Sümegi et al. 1998; Deli and Sümegi 1999).
Since the Carpathian Basin occupied a transitional position between the Balkanic refugia and the cold-continental tundro-steppe zone during the glacial periods, the post-glacial re-population of the Carpathian Basin proceeded (1) by long-distance dispersal from the more remote (atlanto- and ponto-) Mediterranean and Southern Continental refugia, and (2) also from some adjacent local survival areas, e.g. from North-Western Balkanic (“Illyrian”) versus South Transylvanian (“Dacian”) arboreal refugia. In such cases, the arrows of the Northwards dispersal of the South-Western and South-Eastern populations surround the arid central part of the basin. These components of the flora and fauna extend Northwards through the foothills of the Eastern Alps and Southwest-Pannonian hilly regions on the one hand, and through the hilly regions of the Banat area and the Western foothills of the Transylvanian “Island” mountains (Apuseni Mts.), on the other. In some cases, the populations of the South-Western and South-Eastern “strains” do not display any significant taxonomical differentiation, e.g. the silver lime (Tilia tomentosa) or some butterflies and moths (Pyronia tithonus, Aplasta ononaria, Idaea nitidata, Zanclognatha tenuialis). Much more evidence is provided by the re-population of the Carpathian Basin from different directions in the cases of vicarious pairs of closely related species or in subspecies of polycentric species. Such cases can mostly be mentioned in land gastropods, e.g. Pomatias elegans - P. rivulare, Chilostoma illyricum - Ch. banaticum, or in flightless insects, e.g. short-winged Orthoptera: Odontopodisma schmidti - O. rubripes, Isophya modestior - I. stysi (Orci et al. 2005).
The Western Balkanic (“Illyrean”) influences are most significant in the Southern and South-Western parts of Transdanubia. These areas are characterised by a humid sub-Mediterranean climate and do not have a significant rainfall deficit in the summer period. They belong to the belt of mesophilous zonal forests of Fagion illyricum and Querco-Carpinion illyricum and the Illyrean-Pannonian hardwood gallery forests (Fraxino pannonicae-Ulmetum) characterised by a richness in tertiary/inter-glacial relict, often geophytic plant species (Horvat et al. 1974).
The Transylvanian (“Dacian”) influences are connected with the forested areas of the Eastern Carpathians and often transmitted by the Western Transylvanian mountains (Mahunka 1993, 2007; Varga 1989, 1995, 2003a,b). The occurrence of Dacian elements is typical of the Eastern part of the Hungarian Middle Range, especially in the higher parts of the volcanic Eperjes-Tokaj range and in the Karst areas of N Hungary and S Slovakia. Eastern Balkanic influences reach also the Hungarian Middle Range by relict-like occurrences of some Balkanic and Balkanic-Anatolian elements (e.g. Noctuidae: A. syriacus and D. schmidtii), especially in the warm foothill zone where the sub-Mediterranean influences are also significant. Relict occurrences of Dacian elements (bush-crickets: Isophya stysi, Leptophyes discoidalis, Pholidoptera transsylvanica; ground-beetles: Carabus hampei ormayi) have been recently discovered on the small, island-like volcanic hills of the Bereg lowland.
The influences of the Northern Carpathians are also significant in the NE part of the Hungarian Middle Range. There is a characteristic difference between the Eperjes-Tokaj volcanic chain on the one hand, and the limestone plateau of the Bükk Mts. and the N Hungarian karst on the other. The biotic contact of the Eperjes-Tokaj range with the Carpathians is young, obviously post-glacial, and can be characterised mostly by the presence of species, which are either typical of the montane forest belts of the Carpathians (e.g. numerous land snails: Bielzia coerulans, Vestia gulo and ground-beetles: Carabus obsoletus, C. zawadszkyi, Abax schueppeli) or widely dispersed in the Northern part of Central Europe, often having a Euro-Siberian distribution. The Bükk Mts., however, display an insular character. Its Carpathian and de-Alpine elements (e.g. land snails: Spelaeodiscus triaria, Phenacolimax annularis, the Geometrid moth Entephria cyanata gerennae) are isolated relicts. In the Aggtelek Karst area, the immediate contact with the higher limestone plateaus of Slovakia is combined with the occurrence of Carpathian (land snails: B. coerulans, Cochlodina cerata, Trichia unidentata; ground-beetles: C. obsoletus, C. zawadszkyi, A. schueppeli, Trichotichnus laevicollis carpathicus), boreal and xeromontane species at surprisingly low altitudes, influenced by the conspicuous meso-climatic and geomorphological features of this area. Some influences of the Northern and the Eastern Carpathians are to be observed at the NE marginal areas of the Pannonian lowland, i.e. along the upper course of the river Tisza and its tributaries (e.g. occurrence of land gastropods Vitrea diaphana, B. coerulans, Balea stabilis, Perforatella dibothrion, P. vicina).
4.3 The Forest: Steppe Dynamics in the Carpathian Basin
The Carpathian Basin belongs to the regions of Europe with the highest biodiversity (Williams et al. 1999). Due to its transitional position during the Quaternary climatic fluctuations, the overlap and accumulation of floristic and faunistic elements of contrasting habitats occurred here. This overlapping of different climatic provinces, enhanced by the varied relief, edaphic and hydrographic conditions, has resulted in suitable conditions for the survival of a large number of species belonging to different core areas and displaying various patterns of long-distance and short-distance re-populations.
It is typical for South-Eastern Central Europe that the large-scaled zonal settling of vegetation, characteristically developed in the East-European table-land, breaks down. In the Carpathian Basin, the concentric arrangement of vegetation belts is influenced by numerous climatic, orographic, hydrographic and edaphic factors (Varga 1995, 2003b). The forest-steppe, which is typical in the major, central lowland and hilly parts of the basin, is represented by a number of regional variants showing distinct geological, edaphic and meso-climatic characters. The forest, skirt and grassland compartments of each regional variant of the forest-steppe are highly intercorrelated. The Carpathians transmit (e.g. boreal) also filter certain different (e.g. steppic) biogeographical influences. Populations passing through the Carpathians will often be isolated and differentiated from the populations inhabiting other parts of their range of distribution.
The geographically transitional position of the Carpathian Basin resulted in a conspicuous mixture of faunal elements of diverse origins and geographical histories. The compartment structure of the vegetation complexes, typical for the Pannonian forest-steppe, has promoted the survival of very different faunal elements. Especially, the hilly areas of transitional climatic conditions surrounding the Pannonian lowland are populated by numerous, biogeographically important species and communities. The Southern, xerothermic slopes and foothills of the Hungarian Middle Range served both as refuges for thermo-xerophilous elements during several cold and cool-humid climatic phases of the Quaternary and as centres of their dispersal (Soó 1940, 1959; Wendelberger 1954, 1959; Zólyomi 1949, 1953, 1964). Thus, many thermophilous elements probably populated the Carpathian Basin not only by long-distance colonisation from remote, large glacial refuges, but also from numerous meso- or microclimatically favourable sites lying at the fluctuating borderlines of the Mediterranean refugial and periglacial belts. The varied and fine biostratigraphical structure of the Hungarian young Pleistocene, often characterised by a coexistence of forest and non-forest faunal elements (e.g. Jánossy 1979; Kordos 1977; Kretzoi 1969, 1977), provides evidences to support this view and demonstrates the transitional biogeographical character of this region during the whole time-span of the Quaternary period. New palynological data from the Eastern part of the Pannonian lowland (Bátorliget) also suggest the presence of forest refuges during the last glacial period (see also: 3.2.).
4.4 Relict Species with Long-Distance Disjunctionsin the Carpathian Basin
There are several Mediterranean-Manchurian bicentric faunal elements with disjunct range occurring in the Carpathian Basin. The distribution of this species group is connected with the Ponto-Caspian waterway-system, and displays long-distance disjunctions from the vicarious Eastern Asiatic taxa, which often are only subspecifically differentiated (Lepidoptera: Apatura metis metis - Apatura m. substituta, Chariaspilates formosarius hungaricus - Chariaspilates f. formosarius, Rhyparioides m. metelkanus - Rhyparioides metelkanus flavidus, Arytrura musculus ssp. - Arytrura m. musculus). These and also some other species of this group (Polypogon gryphalis, Herminia tenuialis, Diachrysia nadeja) occur at the lower course of the Danube and the Drava as well as in swampy-boggy areas of the lowlands in Transdanubia, in the Banat and Eastern Hungary. The refugia of these faunal elements were probably along the lower courses of the Danube and its tributaries. Gallery forests of the Illyrian and the Pannonian type and alluvial wetlands accompanying the large rivers of the Pannonian lowland served as corridors for the Northwards expansion of these species.
Different types of long-distance disjunctions have been observed in the relict-like steppe and semi-desert species. The polytypic butterfly Melanargia russiae, which is widespread in West and Central Asia, South Siberia and in the mountains of Italy and the Balkan Peninsula, occurred locally - as M. russiae clotho - on tall-grass clearings of birch gallery forests of the sandy lowland in Kiskunság. Its extinction was partly due to the consequence of overcollecting, and mostly because of destroying the habitats (re-forestation with Robinia pseudoacacia). The habitats of Chondrosoma fiduciarium (Kasy 1965) are also tall-grass lowland and hilly steppes often mixed with slightly saline patches. Other species are confined to open dolomitic rocky swards (e.g. Phyllometra culminaria, Lignyoptera fumidaria, C. mixta lorica) or open sandy and rupicolous grasslands (Oxytripia orbiculosa, vanishing).
Eremic species are restricted to semi-desert-like habitats of the lowland with extreme edaphic conditions. This faunal type is represented by very few vertebrates: only the small rodent Sicista subtilis and the short-toed lark Calandrella brachydactyla belong to this group. Abundant examples can be found in strictly localised phytophagous insects, which are often connected with special halophytic plant communities. They are often represented by endemic Pannonian subspecies or allopatric sibling species of Turanian origin, e.g. the Noctuid moths Saragossa porosa kenderesiensis and H. dianthi hungarica or the Microlepidoptera: Coleophora hungariae, C. klimeschiella, C. magyarica, C. peisoniella, Holcophora statices, Stenodes coenosana, Agriphila tersella hungarica, etc. The dispersal of this species group could have taken place in the late glacial phases on the Pannonian lowland, with a subsequent isolation as a result of the post-glacial expansion of the forested belts.
Last but not the least, xeromontane elements are present also in the Carpathian Basin. Their two main groups are: the Mediterranean-xeromontane species, represented by a few vertebrates (e.g. Monticola saxatilis or the secondarily more expanded Phoenicurus ochrurus). A larger number of species, however, belongs to some insect groups, e.g. Noctuidae (E. vitta, E. decora, E. birivia, Dichagyris candelisequa, Yigoga nigrescens, Chersotis margaritacea, Ch. fimbriola, Apamea platinea, etc.) and Orthoptera (e.g. Paracaloptenus caloptenoides). The continental-xeromontane type is represented by some members of widely distributed Asiatic mountain steppe species as Euxoa recussa, Dichagyris musiva (Noctuidae) and by some relict-like inhabitants of the rocky dolomit grasslands as P. culminaria, L. fumidaria (Geometridae). It seems to be very probable that numerous genera, typical for the steppe biome, might have a xeromontane origin (especially Lycaenidae: e.g. the subgenus Agrodiaetus and other species groups of Polyommatus and Plebeius; Satyridae: Chazara, Pseudochazara, Hyponephele; Noctuidae: Euxoa, Agrotis, Dichagyris, Yigoga, Rhyacia, Chersotis, Eugnorisma, etc.). The same has to be supposed in the case of some endemic elements of the Pannonian flora (Linum dolomiticum, Seseli leucospermum, Ferula sadleriana, Onosma tornense, etc.).
5 Summary and Conclusions
The European fauna has traditionally been subdivided into a “holothermic” refugial and a “holopsychric” invasion type. The former type was differentiated according to the secondary subdivision of the Mediterranean refugial area. This view was confirmed and modulated by molecular results. A general conclusion was that temperate species mainly derive from Mediterranean refugial populations that underwent range expansion in the late glacial and early post-glacial periods. The other main group has been considered for a long time as a result of the “Siberian” invasion despite the evidences, which have revealed the taxonomical differentiation of North-Eastern “boreal” and Southern European montane populations. Several authors have suggested an additional mode of colonisation of Central and Northern Europe by non-Mediterranean populations, coming from one or more “continental” refugia. Fossil pollen data and macrofossil remains from the time of the Last Glacial Maximum indicate that several tree species remained in small favourable spots at the Southern edge of the steppe-tundra area. Research on small mammals has also questioned the universality of Mediterranean refugia. It was suggested that the Mediterranean “sanctuaria” in general were not also core areas of post-glacial expansion into deglaciated areas.
The Pleistocene glacial-interglacial cycles have resulted in the “antagonistic dynamics” of biota pertaining to contrasting macrohabitats. Principally, two basic types of zonal setting can be distinguished. The glacial periods have been characterised by a regressive fragmentation of wooded habitats and, consequently, by a broad contact of the tundra and the steppe zonobiomes with some forested “pockets” North of the refugial belt of the Mediterranean area. Transitional zono-ecotones developed at the forest-belt fringes: tundra-taiga and boreal forest-steppe. Pollen-based “tree-less tundra” models for Europe, North of the transverse mountain ranges, have repeatedly been questioned by researchers of the late Pleistocene mammalian fauna because the carrying capacity sufficient to feed numerous large herbivores demands a very productive environment (“mammoth steppe”). Thus, non-analogue communities were composed by mixing tundral, steppic and eremic-oreal elements. This boreal forest-steppe habitat type appears to have included also cold-tolerant species of temperate habitats.
The species of the boreal zone show a significant diversity of extension and of taxonomical structure of ranges. Comparison of phylogeographic structures in several Eurasiatic boreal species has shown that species associated with the taiga forest revealed essentially similar patterns. The number of exclusively European boreal and boreo-montane species is relatively low. However, a molecular biogeographical analysis of such species can unravel the European coniferous forest refugia. The existence of European coniferous forest refugia is also supported by the East-West subdivision of several boreal species. Temperate refugia in Europe during cold periods might not have been restricted to the three Southern peninsulas. These refugia were most likely to be located near the Alps or in the Carpathians and, possibly, at the network of streams in the marginal areas of the Carpathian Basin.
The level of endemism generally correlates with the geological age of the refugia where relict-like taxa have been evolved and/or could survive. The Carpathian Basin belongs to the geologically youngest areas of Europe. Its relief developed under the influence of the Alpine orogenesis and by retreat of the Paratethys and the Pannonian inland sea. There are, however, some taxonomical groups which show considerable proportion of endemic species (land gastropods, earthworms or some soil arthropods). Most endemic species are narrow specialists inhabiting extreme habitats, e.g. thermal springs, karstic caves and karstic springs. A bulk of these endemic taxa is confined to the Eastern and Southern Carpathians, to the Apuseni Mts. and to the mountains of Banat, which could preserve relict species or some narrow endemics in refugia without permafrost phenomena during the last glaciations. Since the Carpathian Basin occupied a transitional position between the Balkanic refugia and the cold-continental tundro-steppe zone during the glacial periods, the post-glacial re-population of the Carpathian Basin was preceeded (1) by long-distance dispersal from the more remote (atlanto- and ponto-) Mediterranean and Southern continental refugia, and (2) also from some adjacent local survival areas, e.g. from North-Western Balkanic (“Illyrian”) versus South Transylvanian (“Dacian”) arboreal refugia. In such cases, the arrows of the Northwards dispersal of the South-Western and South-Eastern populations surround the arid central part of the basin.
In the Carpathian Basin, the concentric arrangement of vegetation belts is influenced by numerous climatic, orographic, hydrographic and edaphic factors. The geographically transitional position of the Carpathian Basin resulted in a conspicuous mixture of faunal elements of diverse origins and geographical histories. The compartment structure of the vegetation complexes, typical of the Pannonian forest-steppe, has promoted the survival of very different faunal elements. Thus, many thermophilic elements probably populated the Carpathian Basin not only by long-distance colonisation from remote, large glacial refuges, but also from numerous meso- or microclimatically favourable sites lying at the fluctuating borderlines of the Mediterranean refugial and periglacial belts. Eremic species are restricted to semi-desert-like habitats of the lowland with extreme edaphic conditions. Abundant examples can be found in strictly localised phytophagous insects, which are often connected with special halophytic plant communities. They are often represented by endemic Pannonian subspecies or allopatric sibling species of Turanian origin. The dispersal of this species group could have taken place in the late glacial phases on the Pannonian lowland with a subsequent isolation as a result of the post-glacial expansion of the forested belts. Two main groups of xeromontane elements are present in the Carpathian Basin. A larger number of species of the Mediterranean-xeromontane species belongs to some insect groups, e.g. Noctuidae and Orthoptera. The continental-xeromontane type is represented by some members of widely distributed Asiatic mountain steppe species and by some relict-like inhabitants of the rocky dolomit grasslands. It seems to be very probable that numerous genera, typical of the steppe biome, might have a xeromontane origin.
References
Babik W, Branicki W, Sandera M, Litvinchuk S, Borkin LJ, Irwin JT, Rafinski J (2004) Mitochondrial phylogeography of the moor frog, Rana arvalis. Mol Ecol 13:1469–1480
Bennett KD, Tzedakis PC, Willis KJ (1991) Quaternary refugia of North European trees. J Biogeogr 18:103–115
Bilton DT, Mirol PM, Mascheretti S, Fredga K, Zima J, Searle JB (1998) Mediterranean Europe as an area of endemism for small mammals rather than a source for Northwards post-glacial colonization. Proc R Soc Lond B Biol Sci 265:1219–1226
Björkman L, Feurdean A, Wohlfarth B (2003) Late-Glacial and Holocene forest dynamics at Steregoiu in the Gutaiului Mountains, Northwest Romania. Rev Palaeobot Palynol 124:79–111
Bordács S, Popescu F, Sladed D, Csaikl UM et al (2002) Chloroplast DNA variation of white oaks in Northern Balkans and in the Carpathian Basin. For Ecol Manage 156:197–209
Brunhoff C, Galbreath KE, Fedorov VB, Cook JA, Jaarola M (2003) Holarctic phylogeography of the root vole (Microtus oeconomus): implications for late Quaternary biogeography of high latitudes. Mol Ecol 12:957–968
Bunje PME (2007) Fluvial range expansion, allopatry and parallel evolution in a Danubian snail lineage (Neritidae: Theodoxus). Biol J Linn Soc 90:603–617
Canestrelli D, Cimmaruta R, Costantini V, Nascetti G (2006) Genetic diversity and phylogeography of the Apennine yellow-bellied toad Bombina pachypus, with implications for conservation. Mol Ecol 15:3741–3754
Carcaillet C, Vernet JL (2001) Comments on “the full-glacial forests of central and South-Eastern Europe” by Willis et al. Quat Res 55:385–387
Carlsson M (2003) Phylogeography of the adder (Vipera berus). Ph.D. Theses. Uppsala University
Csuzdi CS, Pop VV (2007) The earthworms of the Carpathian basin (in Hung). In: Forró L (ed) The genesis of the fauna of the Carpathian Basin (in Hung.). Natural History Museum, Budapest, pp 13–20
Dányi L, Traser G (2007) The springtails of Hungary (in Hung.). In: Forró L (ed) The genesis of the fauna of the Carpathian Basin (in Hung.). Natural History Museum, Budapest, pp 21–28
Deffontaine V, Libois R, Kotlík P, Sommer R, Nieberding C, Paradis E, Searle JB, Michaux JR (2005) Beyond the Mediterranean peninsulas: evidence of Central European glacial refugia for a temperate forest mammal species, the bank vole (Clethrionomys glareolus). Mol Ecol 14:1727–1739
Deli T, Sümegi P (1999) Biogeographical characterisation of Szatmár-Bereg plain based on the mollusc fauna. In: Hamar J, Sárkány-Kiss A (eds) The Upper Tisza Valley. Szeged, Tiscia Monograph Series, pp 471–477
Dennis RLH, Williams WR, Shreeve TG (1991) A multivariate approach to the determination of faunal structures among European butterfly species (Lep.: Rhopalocera). Zool J Linn Soc 101:1–49
Duriez O, Sachet JM, Menoni E, Pidancier N, Miquel Ch, Taberlet P (2007) Phylogeography of the capercaillie in Eurasia: what is the conservation status in the Pyrenees and Cantabrian Mounts? Cons Genet 8:513–526
Farcas¸ S, de Beaulieu JL, Reille M, Coldea G, Diaconeasa B, Goeury C, Goslar T, Jull T (1999) First 14C datings of Late Glacial and Holocene pollen sequences from Romanian Carpathes. C R Acad Sci Paris, Sciences de la vie 322:799–807
Farcas¸ S, Miclaus M, Tantau I (2004) Correlations between the actual hilly and plain vegetation from Transylvania and recent-sub-recent palynological spectra. Studii Cercet Biol Bistrita 9:99–111
Fedorov VB, Goropashnaya AV, Jarrell GH, Cook JA (1999) Phylogeographic structure and mitochondrial DNA variation in true lemmings (Lemmus) from the Eurasian Arctic. Biol J Linn Soc 66:357–371
Fedorov VB, Goropashnaya AV, Boeskorov GG, Fredga K (2008) Comparative phylogeography and demographic history of the wood lemming (Myopus schisticolor): implications for late Quaternary history of the taiga species in Eurasia. Mol Ecol 17:598–610
Fedorov VB, Stenseth NC (2002) Multiple glacial refugia in the North American Arctic: inference from phylogeography of the collared lemming (Dicrostonyx groenlandicus). Proc R Soc Lond B Biol Sci 269:2071–2077
Fehér Z, Varga A, Deli T, Domokos T, Szabó K, Bozsó M, Pénzes ZS (2007) Phylogenetic surveys on protected molluscs (in Hung.). In: Forró L (ed) The genesis of the fauna of the Carpathian Basin (in Hung.). Natural History Museum, Budapest, pp 183–200
Fekete G, Varga Z (2006) Pannonian vegetation (in Hung.). In: Fekete G, Varga Z (eds) Vegetation and wildlife of landscapes of Hungary (in Hung.). MTA Társadkut Közp, Budapest, pp 78–80
Feurdean A, Bennike O (2004) Late Quaternary palaeoecological and paleoclimatological reconstruction in the GutaiuluiMountains, NWRomania. J Quat Sci 19:809–827
Feurdean A, Wohlfarth B, Björkman L, Tantau I, Bennike O, Willis KJ, Farcas S, Robertsson AM (2007a) The influence of refugial population on Lateglacial and early Holocene vegetational changes in Romania. Rev Palaeobot Palynol 145:305–320
Feurdean A, Mosbrugger V, Onac BP, Polyak V, Veres D (2007b) Younger Dryas to mid-Holocene environmental history of the lowlands of NW Transylvania, Romania. Quat Res 68:364–378
Fink S, Excoffier L, Heckel G (2004) Mitochondrial gene diversity in the common vole Microtus arvalis shaped by historical divergence and local adaptations. Mol Ecol 13:3501–3514
Finnie TJR, Preston CD, Hill MO, Uotila P, Crawley MJ (2007) Floristic elements in European vascular plants: an analysis based on Atlas Florae Europaeae. J Biogeogr 34:1848–1872
Frenzel B (1992) European climate reconstructed from documentary data, methods and results. Gustav Fischer, Stuttgart
Fumagalli L, Hausser J, Taberlet P, Gielly L, Steward DT (1996) Phylogenetic structure of the Holarctic Sorex araneus group and its relationship with S. samniticus, as inferred from mtDNA sequences. Hereditas 125:191–199
Füköh L, Krolopp E, Sümegi P (1995) Quaternary malacostratigraphy in Hungary. Malacol Newsl 1(Suppl):1–219
Gömöry D, Paule L, Shvadchak IM, Popescu F, Sukowska M, Hynek V, Longauer R (2003) Spatial patterns of the genetic differentiation in European beech (Fagus sylvatica L.) at allozyme loci in the Carpathians and the adjacent regions. Silvae Genet 52:78–83
Guthrie RD (1990) Frozen fauna of the mammoth steppe: the story of blue babe. University of Chicago Press, London
Guthrie RD (2000) Origin and cause of the mammoth steppe: a story of cloud cover, woolly mammal tooth pits, buckles, and inside-out Beringia. Quat Sci Rev 20:549–574
Guthrie D, van Kolfschoten T (1999) Neither warm and moist nor cold and arid: the ecology of the Mid Upper Palaeolithic. In: Roebroeks W, Mussi W, Svoboda J, Fennema K (eds) Hunters of the golden age, 31. Analecta Prehistorica, Leiden, pp 13–20
Haase M, Misof B, Wirth T, Baminger H, Baur B (2003) Mitochondrial differentiation in a polymorphic land snail: evidence for Pleistocene survival within the boundaries of permafrost. J Evol Biol 16:415–428
Haynes S, Jaarola M, Searle JB (2003) Phylogeography of the common vole (Microtus arvalis) with particular emphasis on the colonization of the Orkney archipelago. Mol Ecol 12:951–956
Hertelendy E, Sümegi P, Szöör G (1992) Geochronological and paleoclimatic characterisation of Quaternary sediments in the Great Hungarian Plain. Radiocarbon 34:833–839
Hewitt GM (1996) Some genetic consequences of ice ages and their role in divergence and speciation. Biol J Linn Soc 58:247–276
Hewitt GM (1999) Post-glacial re-colonisation of European biota. Biol J Linn Soc 68:87–112
Hewitt GM (2000) The genetic legacy of the Quaternary ice ages. Nature 405:907–913
Hewitt GM (2001) Speciation, hybrid zones and phylogeography - or seeing genes in space and time. Mol Ecol 10:537–549
Hewitt GM (2004) Genetic consequences of climatic oscillation in the Quaternary. Phil Trans R Soc Lond B 359:183–195
Hofmann E (1873) Die Isoporien der europäischer Tagfalter. Dissertatio, Phil. Fac., Jena.
Hofman S, Spolsky Ch, Uzzel Th, Cogalniceanu D, Babik W, Szymura JM (2007) Phylogeography of the fire-bellied toads Bombina :independent Pleistocene histories inferred from mitochondrial genomes. Mol Ecol 16:2301–2316
Horvat I, Glavac V, Ellenberg H (1974) Die Vegetation Südosteuropas. Gustav Fischer, Stuttgart
Huntley B, Birks HJB (1983) An Atlas of past and present pollen maps for Europe: 0–13, 000 years ago. Cambridge University Press, Cambridge
Huntley B, Allen JRM (2003) Glacial environments III. Palaeovegetation patterns in late glacial Europe. In: van Andel TH, Davies SW (eds) Neanderthals and modern humans in the European landscape during the last glaciation. McDonald Institute for Archaeological Research, Cambridge, pp 79–102
Iversen J (1958) The bearing of glacial and interglacial epochs on the formation and extinction of plant taxa. In: Hedberg O (ed.): Systematics of to-day. Uppsala Univ. Arsskr. 6:210–215
Jaarola M, Searle JB (2002) Phylogeography of field voles (Microtus agrestis) in Eurasia inferred from mitochondrial DNA sequences. Mol Ecol 11:2613–2621
Jánossy D (1979) Subdivision of the Hungarian Pleistocene on the basis of vertebrate fauna (in Hung.). Akadémiai Kiadó, Budapest
Kasy F (1965) Zur Kenntnis der Schmetterlingsfauna des östlichen Neusiedlersee-Gebietes. Wissensch Arb Burgenland (Eisenstadt) 34:75–211
Kis B (1965) Zubovskia banatica, eine neue Orthoptera-Art aus Rumänien. Reichenbachia, Abhandl Mus Tierkunde, Dresden 5:5–8
Kis B (1980) Die endemischen Orthopteren in der Fauna von Rumänien. Muz Brukenthal, Stud Comunic 24:421–431
Kordos L (1977) A sketch of the biostratigraphy of the Hungarian Holocene (in Hung.). Földr Közl 25:144–160
Korsós Z (1994) Checklist, preliminary distribution maps and bibliography of Millipedes of Hungary (Diplopoda). Misc zool hung 9:29–82
Kostrowicki AS (1969) Geography of the Palearctic papilionoidea (Lepidoptera). Panstwowe Wydawnictwo Naukowe, Warszawa
Kotlík P, Deffontaine V, Mascheretti S, Zima J, Michaux JR, Searle JB (2006) A Northern glacial refugium for bank voles (Chlethrionomys glareolus). Proc Natl Acad Sci USA 103(40):14860–14864
Kretzoi M (1969) Sketch of the late Cenozoic terrestrial biostratigraphy of Hungary (in Hung.). Földr Közl 16(92):179–198
Kretzoi M (1977) Ecological Conditions of the “Loess” Period in Hungary as Revealed from the Vertebrate Fauna (in Hung.). Földr Közl 25:75–93
Krolopp E, Sümegi P (1995) Palaeoecological reconstruction of the late Pleistocene, based on loess malacofauna in Hungary. GeoJournal 36(2–3):213–222
Kupriyanova LA, Mayer W, Böhme W (2006) Karyotype diversity of the Eurasian lizard Zootoca vivipara (Jacquin, 1787) from Central Europe and the evolution of viviparity. In: Vences M, Köhler J, Ziegler T, Böhme W (eds): Herpetologia Bonnensis II. Proceedings of the 13th of the Congress Society European Herpetology pp. 67–72
Lattin G de (1949) Beiträge zur Zoogeographie des Mittelmeergebietes. Verh dtsch zool Ges Kiel Zool Anz Suppl 13 (1948): 143–151
Lattin G de (1957) Die Ausbreitungszentren der holarktischen Landtierwelt. Verh dtsch zool Ges Hamburg Zool Anz Suppl 21 (1956): 380–410
de Lattin G (1964) Die Verbreitung des sibirischen Faunenelements in der Westpaläarktis. Nat Mus 94:104–125
de Lattin G (1967) Grundriss der Zoogeographie. Gustav Fischer, Stuttgart
Litynska-Zajac M (1995) Anthracological analysis. In: Hromada J, Kozlowski J (eds) Complex of upper palaeolithic sites near. Jagellonian University Press, Moravany, Western Slovakia, pp 74–79
Magri D (2007) Patterns of post-glacial spread and the extent of glacial refugia of European beech (Fagus sylvatica). J. Biogeogr. doi:10.1111/j.1365–2699.2007.01803.x
Magri D, Vendramin GG, Comps B, Dupanloup I et al (2006) A new scenario for the Quaternary history of European beech populations: palaeobotanical evidence and genetic consequences. New Phytol 171:199–221
Mahunka S (1993) Hungaromotrichus baloghi gen. et sp. n. (Acari: Oribatida), and some suggestions to the faunagenesis of the Carpathian basin. Folia ent hung 54:75–83
Mahunka S (2007) The oribatid mites of the Carpathian basin (in Hung.). In: Forró L (ed) The genesis of the fauna of the Carpathian Basin. Natural History Museum, Budapest, pp 37–44
Magyari E, Jakab G, Rudner E, Sümegi P (1999) Palynologicaland plant macrofossil data on Late Pleistocene short term climatic oscillations in North-east Hungary. Acta Palaeobot, Suppl 2:491–502
Michaux JR, Magnanou E, Paradis E, Nieberding C, Libois RM (2003) Mitochondrial phylogeography of the woodmouse (Apodemus sylvaticus) in the Western Palearctic region. Mol Ecol 12:685–697
Nève G (1996) Dispersion chez un espèce à habitat fragmenté: Proclossiana eunomia (Lepidoptera, Nymphalidae). Dissertation, University of catholique de Louvain, Louvain-la-Neuve, pp. 1–128
Orci KM, Nagy B, Szövényi G, Rácz IA, Varga Z (2005) A comparative study on the song and morphology of Isophya stysi Cejchan, 1958 and I. modestior Brunner von Wattenwyl, 1882. Zool Anz 244:31–42
Oshida T, Abramov A, Yanagava H, Masuda R (2005) Phylogeography of the Russian flying squirrel (Pteromys volans): implication of refugia theory in arboreal small mammal of Eurasia. Mol Ecol 14:1191–1196
Petit RJ, Csaikl UM, Bordács S et al (2002) Chloroplast DNA variation in European white oaks. Phylogeography and patterns of diversity based on data from over 2600 populations. For Ecol Manage 156:5–26
Petit RJ, Aguinagalde I, de Beaulieu J-L, Bittkau C, Brewer S, Cheddadi R, Ennos R, Fineschi S, Grivet D, Lascoux M, Mohnty A, Müller-Starck G, Demesure-Musch B, Palmé A, Pedro Martin J, Rendell S, Vendramin GG (2003) Glacial refugia: hotspots but not melting pots of genetic diversity. Science 300:1563–1565
Pinceel J, Jordaens K, Pfenninger M, Backeljau T (2005) Rangewide phylogeography of a terrestrial slug in Europe: evidence for Alpine refugia and rapid colonization after the Pleistocene glaciations. Mol Ecol 14:1133–1150
Pokorny P, Jankovská V (2000) Long-term vegetation dynamics and the infilling process of a former lake (Svarcenberk, Czech Republic). Folia Geobot 35:433–457
Rácz GR, Gubányi A, Vozár Á (2005) Morphometric differences among root vole (Muridae: Microtus oeconomus) populations in Hungary. Acta Zool Hung 51:39–53
Rebel H (1931) Zur Frage der europäischen Faunenelemente. Ann Nathist Mus Wien 46:49–55
Reinig W (1950) Chorologische Voraussetzungen für die Analyse von Formenkreisen. Syllegomena biol. Festschr Kleinschmidt, Leipzig, pp 346–378
Rudner ZE, Sümegi P (2001) Recurring Taiga forest-steppe habitats in the Carpathian Basin in the Upper Weichselian. Quat Int 76(77):177–189
Rybnıcková E, Rybnıcek K (1991) In: Kovar-Eder J (ed.): Palaeovegetational development in Europe and regions relevant to its plaeofloristic evolution. Mus Nat Hist Vienna, pp. 73–79
Saarma U, Ho SYW, Pybus OG, Kaljuste M et al (2007) Mitogenetic structure of brown bears (Ursus arctos L.) in North-Eastern Europe and a new time frame for the formation of European brown bear lineages. Mol Ecol 16:401–413
Scharff RF (1899) The history of the European fauna. Walter Scott, London
Schirrmeister L, Siegert C, Kuznetsova T et al (2002) Paleoenvironmental and paleoclimatic records from permafrost deposits in the Arctic region of Northern Siberia. Quat Int 89:97–118
Schmitt T (2007) Molecular biogeography of Europe: Pleistocene cycles and postglacial trends. Front Zool 4:11. doi:10.1186/1742-9994-4-11
Schmitt T, Hewitt G (2004) The genetic pattern of population threat and loss: a case study of butterflies. Mol Ecol 13:21–31
Schmitt T, Haubrich K (2008) The genetic structure of the mountain forest butterfly Erebia euryale unravels the late Pleistocene and Postglacial history of the mountain forest biome in Europe. Mol Ecol 17:2194–2207
Schmitt T, Rákosy L, Abadjiev S, Müller P (2007) Multiple differentiation centres of a non-Mediterranean butterfly species in South-Eastern Europe. J Biogeogr 34:939–950
Schmitt T, Seitz A (2001) Intraspecific allozymatic differentiation reveals the glacial refugia and the postglacial expansions of European Erebia medusa (Lepidoptera, Nymphalidae). Biol J Linn Soc 74:429–458
Simakova AA (2001) The vegetation and mammoth distribution during the second half of the Late Pleistocene on the Russian Plain (33–17 ka). The World of Elephants, International Congress, Rome 2001, pp. 355–358
Sjörs H (1963) Amphi-Atlantic zonation, from Nemoral to Arctic. In: Löve A, Löve D (eds) North Atlantic biota and their history. Pergamon Press, Oxford, pp 109–126
Soó R (1940) Vergangenheit und Gegenwart der pannonischen Flora und Vegetation. Nova Acta Leopold 9:1–49
Soó R (1959) Streitfragen über die Entstehung der Vegetation des Alföld und ihre heutige Beurteilung. Földr Ért 8:1–26
Soós L (1943) The mollusca fauna of the carpathian basin (in Hung) természettud. Társulat, Budapest
Stegmann B (1932) Herkunft der paläarktischen Taiga-Vögel. Arch Naturgesch (NF) 1:392–397
Stegmann B (1938) Grundzüge der ornithogeographischen Gliederung des paläarktischen Gebietes. Fauna SSSR, Moscow Leningrad
Steward JR, Lister AM (2001) Cryptic Northern refugia and the origins of the modern biota. TREE 16:608–613
Sümegi P, Hertelendi E, Magyari E et al (1998) Evolution of the environment in the Carpathian Basin during the last 30,000 BP years and its effects on the ancient habits of the different cultures. In: Költő L, Bartosiewicz L (eds.): the Archeological Inst. of the Hungarian Academy of Sciences (HAS), vol II, Budapest, pp. 183–197
Sümegi P, Krolopp E (2002) Quatermalocological analyses for modelling the Upper Weichselian palaeoenvironmental changes in the Carpathian basin. Quat Int 91:53–63
Sümegi P, Rudner ZE (2001) In situ charcoal fragments as remains of natural wild fires in the upper Würm of the Carpathian Basin. Quat Int 76(77):165–176
Surget-Groba Y, Heulin B, Guillaume C-P, Thorpe R et al (2001) Intraspecifi c phylogeography of Lacerta vivipara and the evolution of viviparity. Mol Phylogenet Evol 18:449–459
Surget-Groba Y, Heulin B, Guillaume C-P, Puky M, Semenov B, Orlova V, Kupriyanova L, Ghira I, Smajda B (2006) Multiple origins of viviparity, or reversal from viviparity to oviparity and the evolution of parity. Biol J Linn Soc 87:1–11
Svendsen JI, Astakhov VI, Bolshiyanov DY et al (1999) Maximum extent of the Eurasian ice sheets in the Barents and Kara Sea region during the Weichselian. Boreas 28:234–242
Svendsen JI, Alexanderson H, Astakhov VI et al (2004) Late Quaternary ice sheet history of Northern Eurasia. Quat Sci Rev 23:1229–1271
Szymura JM, Uzzell T, Spolsky C (2000) Mitochondrial DNA variation in the hybridising fire-bellied toads, Bombina bombina and B. variegata. Mol Ecol 9:891–899
Taberlet P, Bouvet J (1994) Mitochondrial DNA polymorphism, phylogeography and conservation genetics of the brown bear (Ursus arctos) in Europe. Proc R Soc Lond B 255:195–200
Taberlet P, Fumagalli L, Wust-Saucy A-G, Cosson J-F (1998) Comparative phylogeography and postglacial colonisation routes in Europe. Mol Ecol 7:453–464
Tantau I, Reille M, de Beaulieu J-L, Farcaş S, Goslar T, Paterne M (2003) Vegetation history in the Eastern Romanian Carpathians: pollen analysis of two sequences from the Mohos crater. Veget Hist Archaeobot 12:113–125
Tantau I, Reille M, de Beaulieu J-L, Farcaş S (2006) Late Glacial and Holocene vegetation history in the Southern part of Transylvania (Romania): pollen analysis of two sequences from Avrig. J Quat Sci 21:49–61
Tarasov PE, Volkova VS, Webb T (2000) Last glacial maximum biomes reconstructed from pollen and plant macrofossil data from Northern Eurasia. J Biogeogr 27:609–620
Ursenbacher S, Carlsson M, Helfer V, Tegelström H, Fumagalli L (2006) Phylogeography and Pleistocene refugia of the adder (Vipera berus) as inferred from mitochondrial DNA sequence data. Mol Ecol 15:3425–3437
Valdiosera CE, Garcia N, Anderlung C, Dalen L, Cregut-Bonnoure E, Kahlke R-D, Stiller M, Brandström M, Thomas MG, Arsuaga J-L, Götherström A, Barnes I (2007) Staying out in the cold: glacial refugia and mitochondrial DNA phylogeography in ancient European brown bears. Mol Ecol 16:5140–5148
Van de Zande L, Van Apeldoorn RC, Blijdenstein AF, De Jong D, Van Delden W, Bijlsma R (2000) Microsatellite analysis of population structure and genetic differentiation within and between populations of the root vole, Microtus oeconomus in the Netherlands. Mol Ecol 9:1651–1656
Varga Z (1975) Geographische Isolation und Subspeziation bei den Hochgebirgslepidopteren der Balkanhalbinsel. Acta Ent Jugosl 11:5–39
Varga Z (1977) Das Prinzip der areal-analytischen Methode in der Zoogeographie und die Faunenelemente-Einteilung der europäischen Tagschmetterlinge. Acta Biol Debr 14:223–285
Varga Z (1989) Die Waldsteppen des pannonischen Raumes aus biogeographischer Sicht. Düsseldorfer geobot Kolloq 6:35–50
Varga Z (1995) Geographical patterns of biodiversity in the Palearctic and in the carpathian basin. Acta Zool Hung 41:71–92
Varga Z (2002): Post-glacial dispersal strategies of Orthoptera and Lepidoptera in Europe and in the Carpathian basin. In: Proceedings of 13th International Colloquium of EIS, Leiden, pp. 93–105
Varga Z (2003a) The geographical distribution of high mountain macrolepidoptera in Europe. In: Nagy L, Grabherr G, Körner C, Thompson DBA (eds) Alpine biodiversity in Europe. Springer, Berlin, pp 239–257
Varga Z (2003b) Zoogeography of the Carpathian basin (in Hung.). In: Láng I, Bedő Z, Csete L (eds) Flora, Fauna, Habitats, vol III, Magyar Tudománytár. MTA Társadkut Közp, Budapest, pp 89–119
Varga Z (2006) Faunal history and biogeography of the Carpathian basin. In: Fekete G, Varga Z (eds) Vegetation and wildlife of landscapes of Hungary (in Hung.). MTA Társadkut Közp, Budapest, pp 44–75
Varga Z, Gyulai I (1978) Die Faunenelemente-Einteilung der Noctuiden Ungarns und die Verteilung der Faunenelemente in den Lokalfaunen. Acta Biol Debr 15:257–295
Varga Z, Peregovits L, Ronkay L (1989) Zoogeographical survey of the mongolian noctuidae fauna. Nota Lepid 12(Suppl. 1):63–64
Varga Z, Rákosy L (2009) Biodiversität der Karstgebiete im Karpatenbecken am Beispiel der Gross-Schmetterlingsfauna der Turzii-Schlucht bzw. des Aggteleker Karstgebietes. In: Proceedings of Congress SIEEC Cluj-Napoca (2007), (in press)
Velichko AA, Catto N, Drenova AN, Klimanov VA, Kremenetski KV, Nechaev VP (2002) Climate changes in East Europe and Siberia at the Late glacial-holocene transition. Quat Int 91:75–99
Venczel M (1997) Amphibians and reptiles from the lower Pleistocene of Osztramos (Hungary). Nymphaea 23–25:77–88
Voous KH (1960) Atlas of European birds. Nelson, London
Voous KH (1963) The concept of faunal elements or faunal types. Proceedings of the 13 international congress ornithological, pp. 1104–1108
Vörös J, Alcobendas M, Martínez-Solano I, García-París M (2006) Evolution of Bombina bombina and Bombina variegata (Anura: Discoglossidae) in the Carpathian Basin: a history of repeated mt-DNA introgression across species. Mol Phylogen Evol 38:705–718
Walter H, Breckle S-W (1986) Ökologie der Erde. Spezielle Ökologie der Gemäßigten und Arktischen Zonen Euro-Nordasiens. G, Fischer, Stuttgart
Walter H, Straka H (1970) Arealkunde. Floristisch-historische Geobotanik. Ulmer, Stuttgart
Wendelberger G (1954) Steppen, Trockenrasen und Wälder des pannonischen Raumes. Festschr Aichinger 1:574–634
Wendelberger G (1959) Die Waldsteppen des pannonischen Raumes. Veröff geobot Inst Rübel 35:77–113
Widmer A, Lexer CH (2001) Glacial refugia: sanctuaries for allelic richness, but not for gene diversity. TREE 16(No.6):267–269
Williams P, Humphries C, Araújo M (1999) Mapping Europe’s biodiversity. In: Delbaere B (ed) Facts and figures on Europe’s biodiversity, State and Trends 1998–1999. ECNC, Tilburg, pp 12–20
Willis KJ (1994) The vegetational history of the Balkans. Quat Sci Rev 13:769–788
Willis KJ, Sümegi P, Braun M, Tóth A (1995) The late Qarternary environmental history of Bátorliget, NE Hungary. Palaeogeogr Palaeoclimatol Palaeoecol 118:25–47
Willis KJ, Rudner ZE, Sümegi P (2000) Full glacial forests of Central and South Eastern Europe. Quat Res 53:203–213
Willis KJ, van Andel TH (2004) Trees or no trees? The environments of central and Eastern Europe during the Last Glaciation. Quat Sci Rev 23:2369–2387
Willis KJ, Niklas K (2004) The role of Quaternary environmental change in plant macroevolution: the exception or the rule? Phil Trans R Soc Lond B 359:159–173
Wohlfarth B, Hannon G, Feurdean A, Ghergari L, Onac BP, Possnert G (2001) Reconstruction of climatic and environmental changes in NW Romania during the early part of the last deglaciation (15,000-13,600 cal yr BP). Quat Sci Rev 20:1897–1914
Yurtsev BA (2001) The Pleistocene ‘‘Tundra-Steppe’’ and the productivity paradox: the landscape approach. In: Elias SA, Brigham-Grette, J (eds.): Beringean Paleoenvironments. Quat Sci Rev 20:165–174
Zink RM, Drovetski SV, Rohwer S (2002) Phylogeographic patterns in the great spotted woodpecker Dendrocopos major across Eurasia. J Avian Biol 33:175–178
Zólyomi B (1949) Die Mitteldonau-Florenscheide und das Dolomitphänomen. Bot Közl 39:209–224
Zólyomi B (1953) Die Entwicklungsgeschichte der Vegetation Ungarns seit dem letzten Interglazial. Acta Biol Hung 4:367–413
Zólyomi B (1964) Pannonische vegetationsprobleme. Verh Zool-Bot Ges Wien 103–104:144–151
Acknowledgements
I am deeply indebted to the precursors of modern phylogeographic thoughts: to the late Gustaf de Lattin and Willy Reinig who inseminated the biogeography by genetic insights and shaped my ideas. The Alexander von Humboldt Foundation repeatedly supported my research fellowships in Germany. The survey of the faunal history of Hungary was partly supported by the grant NKFP-3 B/023/2004.
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Varga, Z. (2009). Extra-Mediterranean Refugia, Post-Glacial Vegetation History and Area Dynamics in Eastern Central Europe. In: Habel, J., Assmann, T. (eds) Relict Species. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-540-92160-8_3
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