Научная статья на тему 'The origin and development of the East European taiga in late Cenozoic'

The origin and development of the East European taiga in late Cenozoic Текст научной статьи по специальности «Биологические науки»

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Russian Journal of Ecosystem Ecology
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бореальные леса / полинологические и остеологические базы данных / ключевые виды / модельная реконструкция / история экосистем / плейстоцен / голоцен / boreal forests / palynological and osteological database / keystone species / model reconstructions / ecosystems history / Pleistocene / Holocene

Аннотация научной статьи по биологическим наукам, автор научной работы — V. N. Kalyakin, S. A. Turubanova, O. V. Smirnova

В данной работе авторы поставили цель пересмотреть представления о современной европейской тайге как естественном типе растительности, сформировавшемся в результате исключительно природных процессов, и обосновать представлении о доминирующей роли антропогенной деятельности в формировании этого типа растительности. Инновационные идеи и новые данные позволили проанализировать различные исторические периоды, характеризующиеся различной интенсивностью и формами активности человека. Палеобиологическая реконструкция териофауны и дендрофлоры от позднего Плиоцена до наших дней позволяет сделать предположение, что первоначальным видом растительности бореальных лесов Плиоцена были хвойно-широколиственные саванные леса Северной Евразии, где крупные травоядные животные (гигантские виды мамонтового комплекса) больше всего оказывали влияние на флору и фауну данной территории. В конце Плейстоцена утрата роли ключевого вида крупными и гигантскими травоядными для травянистых экосистем стало критическим этапом в необратимой трансформации наземной экосистемы. В период Голоцена лесная растительность разделилась на бореальную (тайга), неморальнобореальную и неморальную зоны в результате деятельности человека.

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ПРОИСХОЖДЕНИЕ И РАЗВИТИЕ ВОСТОЧНОЕВРОПЕЙСКОЙ ТАЙГИ В ПОЗДНЕМ КАЙНОЗОЕ

The authors suggest a new aspect of origin and development of the East European boreal forest. Innovative ideas and new data allowed to analyze the genesis of the ecosystem cover by creating a series of model reconstructions of different historical periods with different intensity and forms of human activity. Paleobiological reconstruction of teriofauna and denroflora since the late Pliocene to the present allows assuming that the initial vegetation type for boreal forests was Pliocene coniferous-broad-leaved savanna-looking forests of Northern Eurasia, where large herbivores (giant species of the mammoth complex) affected biota the most. At the end of Pleistocene the loss of the key species’ role of large and giant herbivores for grassland ecosystems was a crucial step in the irreversible transformation of the terrestrial ecosystem. During Holocene forest vegetation split into boreal (taiga), nemoral-boreal and nemoral zones as a result of human activities.

Текст научной работы на тему «The origin and development of the East European taiga in late Cenozoic»

RUSSIAN JOURNAL ^JV OF ECOSYSTEM ECOLOGY Vol. 1 (1), 2016

УДК 56.017.551.891 DOI: 10.21685/2500-0578-2016-1-2 Open Access 1

THE ORIGIN AND DEVELOPMENT OF THE EAST EUROPEAN TAIGA IN LATE CENOZOIC

V. N. Kalyakin

Zoological Museum of Moscow State University, 6 Nikitskaya street, Moscow, 125009, Russia E-mail: kalyakiny1939@mail.ru

S. A. Turubanova

University of Maryland, College Park, Le Frak Hall, 20742, MD, USA E-mail: paleobase@gmail.com

O. V. Smirnova

Center for ecological and forest productivity problems, 84/32 Profsoyuznaya street, Moscow, 117810, Russia E-mail: ovsinfo@gmail.com

ПРОИСХОЖДЕНИЕ И РАЗВИТИЕ ВОСТОЧНОЕВРОПЕЙСКОЙ ТАЙГИ В ПОЗДНЕМ КАЙНОЗОЕ

B. Н. Калякин

Зоологический музей Московского государственного университета, 125009, Россия, г. Москва, ул. Большая Никитская, 6 E-mail: kalyakiny1939@mail.ru

C. А. Турубанова

Университет шата Мэриленд, США, Мэриленд, 20742 Ле ФракХолл,Колледж Парк E-mail: paleobase@gmail.com

О. В. Смирнова

Центр по проблемам экологии и продуктивности лесов РАН, 117485, Россия, г. Москва, ул. Профсоюзная, 84/32 E-mail: ovsinfo@gmail.com

Abstract. The authors suggest a new aspect of origin and development of the East European boreal forest. Innovative ideas and new data allowed to analyze the genesis of the ecosystem cover by creating a series of model reconstructions of different historical periods with different intensity and forms of human activity. Paleobiological reconstruction of teriofauna and denroflora since the late Pliocene to the present allows assuming that the initial vegetation type for boreal forests was Pliocene coniferous-broad-leaved savanna-looking forests of Northern Eurasia, where large herbivores (giant species of the mammoth complex) affected biota the most. At the end of Pleistocene the loss of the key species' role of large and giant herbivores for grassland ecosystems was a crucial step in the irreversible transformation of the terrestrial ecosystem. During Holocene forest vegetation split into boreal (taiga), nemoral-boreal and nemoral zones as a result of human activities.

Key words: boreal forests, palynological and osteological database, keystone species, model reconstructions, ecosystems history, Pleistocene, Holocene.

Аннотация. В данной работе авторы поставили цель пересмотреть представления о современной европейской тайге как естественном типе растительности, сформировавшемся в результате исключительно природных процессов, и обосновать представлении о доминирующей роли антропогенной деятельности в формировании этого типа растительности. Инновационные идеи и новые данные позволили проанализировать различные исторические периоды, характеризующиеся различной интенсивностью и формами активности человека. Палеобиологическая реконструкция териофауны и дендрофлоры от позднего Плиоцена до наших дней позволяет сделать предположение, что первоначальным видом растительности бореальных лесов Плиоцена были хвойно-широколиственные саванные леса Северной Евразии, где крупные травоядные животные (гигантские виды мамонтового комплекса) больше всего оказывали влияние на флору и фауну данной территории. В конце Плейстоцена утрата роли ключевого вида крупными и гигантскими травоядными для травянистых экосистем стало критическим этапом в необратимой трансформации наземной экоси-

© 2016 Kalyakin V. N., Turubanova S. A., Smirnova O. V. Данная статья доступна по условиям всемирной лицензии Creative Commons Page 1 from 26

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стемы. В период Голоцена лесная растительность разделилась на бореальную (тайга), неморально-бореальную и неморальную зоны в результате деятельности человека.

Ключевые слова: бореальные леса, полинологические и остеологические базы данных, ключевые виды, модельная реконструкция, история экосистем, плейстоцен, голоцен.

Introduction

The origin and development of boreal forests of Northern Eurasia has been discussed for decades [1-10]. Another reference to this problem (based on the example from the Eastern European part of the boreal zone) is due to several reasons.

Firstly, the modern theories in synecology show that formation and development of forest ecosystems were affected by keystone species - not only plants, but also animals. These species play a critical role in maintaining the structure of an ecological community, affecting many other organisms in an ecosystem and helping to determine the types and numbers of other various species in the community [10]. In this regard the study of the genesis of boreal forests is possible only through analyzing changes in the composition of both flora and fauna, specifically the keystone species. Accumulated paleontological data is a necessary factual basis for reconstruction modelling of the ecosystem cover.

Secondly, the analysis of the terrestrial ecosystems history since the end of the Pliocene to the present has shown that humans acted as a powerful keystone species, determining composition and structure of actual vegetation even before the producing economy development [10-19].

Therefore, innovative ideas and new data allowed to analyze the genesis of the ecosystem cover by creating a series of model reconstructions of different historical periods with different intensity and forms of human activity. In this article we describe such experience for Eastern Europe.

Objectives: A. series of reconstruction models of formation and development of the taiga (boreal forest) in Eastern Europe since the end of the Pleistocene to nowadays based on comparison of extinct and existing key species of animals and plants expansion, as well as associated assemblies of sub-ordinate(indicator) species;

B. revision of existing hypotheses of the origin of the Eurasian taiga based on the analysis of literature and the data on the key plant and animal species expansion dynamics.

Methods and objects

The basis of the methodology for reconstruction of the boreal zone of Eastern Europe is the idea of the transforming role of key plant and animal species and subordinate species [8, 10, 18, 19]. Since population dynamics of key species creates the

necessary conditions for sustainable habitats of subordinate species, paleontological data of key species presence allows an indirect suggestion about existence of the relevant ecosystems in general.

The mapping methods of former and actual area include as follows:

1. Selection of key and subordinate (indicator) species;

2. Creation of databases i. a palynological and an osteological databases, reported data on locations of the chosen species, herbarium data (the "Areal" database); ii. geobotanical field descriptions from refugia of the boreal forest - the "Forest vegetation of Northern Eurasia" database;

3. Creation of GIS-maps for different time periods from the end of the Pleistocene to nowadays. Table 1 shows synchronization of geochronologi-cal and archaeological scales from the end of the Pleistocene to the Holocene.

Key animal species:

A. extinct everywhere or only in Eurasia: giant deer (Megaloceros giganteus Blumenbach), prehistoric bison (Bison priscus Bojanus), musk ox (Ovibos moschatus Zimmermann), woolly rhinoceros (Coelodonta antiquitatis Blumenbach), Mammoth (Mammuthus primigenius Blumenbach), including species that became instinct during last centuries: wild horse (Equus Linnaeus (sp.)), au-roch (Bos primigenius Bojanus), bison (Bison bonasus Linnaeus). Bison was close to extinction in the beginning of the 20 century, but thanks to special efforts its population was restored on limited areas.

B. survived and/or partially restoring its historic areas: European beaver (Castor fiber Linnaeus), wild boar (Sus scrofa Linnaeus), red deer (Cervus elaphus Linnaeus), roe deer (Capreolus capreolus Linnaeus), moose (Alces alces Linnaeus), reindeer (Rangifer tarandus Linnaeus), saiga (Saiga tatari-ca Linnaeus).

Key plant species survived to nowadays and/or partially restoring its historic areas: species of the genus oak (Quercus sp.), beech (Fagus sp.), ash (Fraxinus sp.), maple (Acer sp.), linden (Tilia sp.), elm (Ulmus sp.), hornbeam (Carpinus sp.), hazel (Corylus sp.), spruce (Picea sp.), fir (Abies sp.), cedar pine (Pinus sibirica). In the pollen spectra, plant macrofossils, data from historical sources and toponyms of trees are determined by genus. The herbarium materials and geobotanical data are listed by the species.

Table 1

Cross-discipline correlation of the Holocene

Geochronological classification Archeological classification (Bader, 1974)

The sequence (Neistadt, 1957) The sequence by Blytt-Sernander (Khotinsky, 1982)

stage stage dating, BP

Late Holocene (HL-4) 0-2500 subatlantic SA-3 SA-2 SA-1 800 1800 2500 Iron age

SB-3 3200

subboreal SB-2 4200 Bronze age

Middle Holocene 2500-7700 SB-1 4600

(HL-3) AT-3 6000

atlantic AT-2 AT-1 7000 8000 N eolith

BO-3 8300

Early Holocene (HL-2) 7700-9800 boreal BO-2 BO-! 8900 9300 Mesolith

preboreal PB-2 10 000

PB-1 10 300

Older Holocene (HL-1) 9800-12000 Dry as Allerod Dr AI 11 000 12 000 Paleolith

Late Pleistocene 13 000 40 000

Maps were created not only for every chosen species but also for the following types: dark coniferous (spruce, fir, cedar pine) and broad-leaved (oak, beech, linden, maple, ash, elm, hornbeam and hazel). All locations of representatives of at least one tree genus from a certain type were considered for mapping a type area.

Indicator plant species were sorted by two complexes: "nemoral" - associated with formation of deciduous broad-leaved trees, and "boreal" - related to formation of dark coniferous (evergreen) trees.

The "nemoral" complex includes two groups differing by its phenology: 1. spring ephemeroids: species of the following genera: Anemone, Coryd-alis, Dentaria, Gagea, and 2.tall herbs and grasses: Aegopodium podagraria L., Asarum europaeum L., Convallaria majalis L., Carexpilosa Scop., Galeobdolon luteum Huds., Lathyrus vernus (L.) Bernh., Melica nutans L., Mercurialis perennis L., Milium effusum L., Paris quadrifoila L., Polygona-tum multiflorum (L.) All., Poa nemoralis L., Pulmonaria obscura Dumort., Ranunculus cassubicus L., Stellaria holostea L., Viola mirabilis L.

The "boreal" complex includes evergreen grass and shrubs: Circaea alpine L., Goodyera repens (L.) R. Br. in Aiton & W.T. Aiton, Gymnocarpium dryopteris (L.) Newman, Linnaea borealis (L.) R. Br., Listera cordata (L.) R. Br., Luzula pilosa (L.) Willd., Maianthemum bifolium (L.) F.W. Schmidt, Moneses uniflora (L.) A. Gray, Oxalis acetosella L., Orthilia secunda (L.) House, Phegopteris con-

nectilis (Michx.) Watt, Pyrola media Sw., P. minor L., P. rotundifolia L., Trientalis europaea L., Vac-cinium myrtillus L., Viola selkirkii Pursh ex Goldie and others [20].

Simultaneous presence of the indicator species in the modern boreal forest we assumed as simultaneous presence of key species in the Past.

Indicator animal species are combined in two complexes, nemoral (deciduous) and forest in general:

Nemoral species are species whose habitats are now confined mainly to the area of present distribution of broad-leaved and coniferous-broad-leaved forests. It is common hedgehog (Erinaceus europaeus Linnaeus), muskrat (Desmana moschata Linnaeus), ordinary mole (Talpa europaea Linnaeus), polecat (Mustela putorius Linnaeus), wild boar (Sus scrofa), red deer (Cervus elaphus), loir (Glis glis Linnaeus) and dormouse: forest dormouse (Dryomys nitedula Pallas), garden dormouse (Eliomys quercinus Linnaeus), hazel dormouse (Muscardinus avellanarius Linnaeus), field mouse (Apodemus agrarius Pallas), three species of forest mice (Sylvaemus Ognev), voles: common pine vole (Microtus subterraneus Selys-Longchamps) and bank vole (Clethrionomys glareolus Schreber).

Forest species in general are species whose habitats are now confined to the entire forest zone, some of them live in the forest tundra and/or the forest steppe: brown bear (Ursus arctos Linnaeus), pine marten (Martes martes Linnaeus), sable (Martes zibellina Linnaeus), European mink

(Mustela lutreola Linnaeus), speakers (Mustela sibirica Pallas), wolverine (Gulo gulo Linnaeus), lynx (Lynx lynx Linnaeus), moose ( Alces alces), red squirrel (Sciurus vulgaris Linnaeus), flying squirrel (Pteromys volans Linnaeus), chipmunk (Tamias sibiricus Laxmann), beaver (Castor fiber), three species of the genus of forest voles (Cle-thrionomys Tilesius): red-haired, red-gray (C. ru-focanus Sundervall) and red vole (C. rutilus Pallas), dark vole (Microtus agrestis Linnaeus) and wood lemming (Myopus schisticolor Lilljeborg).

Species, that were earlier [21] considered boreal, have spread wider [22], therefore, they are included in the forest group. The presence of nemoral plant species and small vertebrates in modern boreal forests is considered as an evidence of former presence of broad-leaved trees [23]. The presence of the same boreal species of shrubs, grasses and small vertebrates from the tundra [24] through the steppes [25] is considered as an evidence of a wider spread of coniferous forests in Eastern Europe.

Research methods and detailed descriptions of the refugia of natural nemoral, hemiboreal and boreal forests were published in a series of articles and monographs [8, 9, 10, 16, 24, 26].

Brief description of model reconstructions of ecosystems of the contemporary forests of Eastern Europe from the late Pleistocene to nowadays

The wood-pasture landscape dominated on the territory of Northern Eurasia not only during the Late Cenozoic (Pliocene to Pleistocene and up to the present), but for some immeasurably longer time. Forest ecosystems were largely confined to the river valleys and slopes including mountain slopes. We agree with the views of A. Krishtofo-vich that "...different facts stand for the development of grassy plains... even later than the Eocene and probably since the Cretaceous period, the century of dinosaurs..." [27, p. 67]. The data analysis [28, 29] conducted by us [19] shows that in the Late Cretaceous (after appearance of angiosperms) the number of genera of dinosaurs herbivores and dinosaurs carnivores drastically (3-3.5 times) increased compared to the Early Cretaceous. At the same time diverse mammal fauna appeared after extinction of dinosaurs, pterosaurs, and several other groups of animals. Large mammals herbivores and large creodonta appeared already in the Palaeocene [28].

In general large herbivores are known even earlier, in the Paleozoic, since the Late Carboniferous -

Early Permian. Grassland pasture ecosystems were formed mainly by ferns before the development of angiosperms according to A. N. Krishto-fovich [27].

Therefore, the analysis shows a long history of pastoral grassland ecosystems formed on the basis of different vegetation, widespread across all continents and several islands in the Northern Hemisphere until the end of the Pleistocene.

The end of the Pleistocene -ancient Holocene (Late Paleolithic) -(40 000-10 000 BP)

At that period the territory of the modern forest zone of Eastern Europe was dominated by wood -pasture ecosystems (forest patches were preserved in river valleys) with mammoth complex representatives as keystone species. Firstly, Mammoth (Mammuthus primigenius Blum.) was the largest key species (Fig. 1.), and, in Europe, in second place were woolly rhinoceros (Coelodonta an-tiquitalis Blum.), prehistoric bison (Bison priscus Boj.) and wild horse (Equus sp.) (Fig. 2).

Populations of large herbivores species of this complex led to suppression of woody vegetation and formation of pasture ecosystems of high productivity [30, 31].

The analysis of radiocarbon dating [32] and data on distribution of key species of plants and animals shows that in the late Pleistocene, during warming and cooling periods, there were stable pasture ecosystems with mixed flora and fauna. The continuity of these ecosystems' dominance throughout the Pleistocene is supported by various authors [18, 19, 28, 33-43].

In the late Wurm (about 110,000 to 12,000 years ago) [44, 45] the Pleistocene maximum regression of the oceans, and, respectively, erosion of the terrain (land relief) were accompanied by increased climate continentality (climate with significant annual temperature variation). This increase concurred with the general trend of cooling (primarily in high latitudes) due to the process of orogenesis, which had begun in the Late Mesozoic Era [46].

It should be noted that the maximum roughness in Late Wurm significantly compensated the climate severity increase. Eroded river valleys (130-140 m lower than now) were not only refugia for many species of flora and fauna, but also served as a channel for broader geographical distribution and vertical dispersal of species. Simultaneously, the growing diversity of the land relief was the reason for increasing patchiness of the

Cl

RUS5IAN JOURNAL ,, , „„ -

of ecosystem ecology Vo1- H1), 2016

ecosystem cover and increased biodiversity. In addition, the development of the river network significantly enhanced penetration of the southern flora and fauna to the north - and northern species to the south. Predominance of open and semi-open landscapes was one of the reasons for existence of the

mixed flora and fauna typical not only for the Late Wurm, but also for prior periods. The main feature of this landscape was the concurrent presence of modern tundra species (arctic foxes and lemmings) and modern steppe species (steppe pikas, steppe marmots, jerboa, hamsters, lemmings, wild horses, saigas, etc.).

Fig. 1. Distribution of mammoth remains in Late Pleistocene (black triangle) and Holocene (white circle)

Fig. 2. Distribution of rhinoceros (Coelodonta antiquitalis) (black triangle), prehistoric bison (Bison priscus) (white square) and wild horse (Equus sp.) (greycircle) remainsinPaleolith

It should be noted that since A. Y. Tugarinov's work in 1929 [47] landscapes of the late Wurm have been attributed to the open type; these were the so-called "tundra-steppe zone" or "periglacial zone". Supporters of the glacial concept followed Gromov [33], suggesting that open landscapes were inhabited mostly by representatives of the "Arctic" fauna, well adapted to the harsh climate of the last glaciation [48-51]. Warming in the Holocene was considered as the main cause of extinction of "arctic" fauna species. However, the gradually accumulated data on the fauna and flora of the Pleistocene and its last period [28, 30, 31, 34, 35, 37-40, 52] indicate its mixed nature. This feature can be satisfactorily explained only in terms of the anti-glacial theory [18, 19, 36, 43, 53-55].

Additional ideas about the fauna of open landscapes was gained when the "Zhiguli" cave opened data on the cave fauna, which is far better pre-

served than plain fauna [56]. The efforts of many authors [41, 57-75] were accumulated in the results that clearly demonstrate the "mixed" composition of terrain fauna (in the upper Pechora basin avifauna also [58]) all over from the lower Pechora River to the South Urals.

This information significantly changes the perception of fauna and the concept of the late Wurm landscapes and specifies terrain fauna changes in the Holocene (Fig. 3, Table 2). In addition, the findings in the caves provided a more complete understanding of the features of Pleistocene landscapes. Thus the findings of a polar bear on the middle Pechora and bird species now confined to a narrow coastal strip of the Arctic Ocean [44] suggest the likelihood of marine transgression (to the north of Eastern Europe - ingression, which flooded mostly river valleys, when the sea level rose).

Fig. 3. Changing of structure of terrain fauna in Ural Mountains from Late Wurm up to present

The mixed nature of the fauna of areas, located relatively close to the cold waters, implies that the ingression had no significant impact on the climate (existence of such mixed fauna would be absolutely impossible during the transgression in this area of the Arctic waters of the Arctic Ocean). A similar situation is currently registered on the coast of the Kara Sea, characterized by high ice cover among the seas of the Eurasian sector [76]. However, Siberian larch, Siberian spruce were registered on the pollen analysis and dendrochronological data just 80 km from the coast on the Hadyta river and its

tributaries [77-79], as well as a large set of boreal species of herbs and shrubs [80].

The Mosaic structure (patchiness) provided unique landscapes of the late Wurm with mixed teriofauna, determined by mountain relief diversity and the impact of key species of the mammoth complex. It was during the warming (Karginskii time), when porcupine Vinogradov and Himalayan bear lived together on the border of the Northern and Middle Urals with typical representatives of the mammoth fauna, and also during the coldest period of the late Wurm ("Polar Ural stadial")

[75, 81], when a polar fox and lemmings, a bank in the Northern Urals together (the Bear's Cave in vole, a moose, a saiga and a wild horse were found the upper Pechora) (Table 2).

Table 2

Trends of fossil mammals remains findings in the Urals Mountain, from the late Paleolith to the Present

Species Habitats Late Paleolith Mezolith Neolith Bronze Age Iron Age 20th cent.

Vinogradov's porcupine Mountains, steppe

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Himalayan bear Nemoral forest

Cave hyena Steppe

Cave lion Steppe

Woolly rhinoceros Steppe

Large cave bear Steppe

Cave bear Steppe

Mammoth Forest-steppe

Saiga Steppe 9

Muskox Steppe 9

Wild horse Steppe f

Polar fox Tundra ?

Hare Forest-steppe 7

Marmot Steppe 7

Long-eared jerboa Steppe ?

Lepus Steppe 9

Eversmann's hamster Steppe 9

Arctic lemming Tundra 9

Siberian brown lemming Tundra 9

Irish elk Forest-steppe 9

Ground squirrel Steppe •t

Aurochs Forest-steppe ?

Bizon Steppe ?

Yellow lemming Steppe ?

Steppe lemming Steppe ?

Steppe polecat Steppe 9

Steppe pika Steppe 9

Gray dwarf hamster Steppe 9

Northern mole vole Steppe 9

Narrow-headed vole Steppe

Red deer Forest-steppe

Roe deer Forest-steppe

Elk Forest

Raindeer Ubiquitous

Wolf Ubiquitous

Fox Ubiquitous

Braun bear Forest

Stoat Ubiquitous

Least weasel Ubiquitous

European mink Ubiquitous

European pine marten Forest

Sable Boreal forest

Wolverine Ubiquitous

Badger Ubiquitous

Otter Ubiquitous

Lynx Forest

Squirrel Forest

Beaver Forest

Mole Nemoral forest ?

Boar Nemoral forest ?

The analysis of paleodata from Eastern Europe pact of climate change and increased pressure of suggests that in periods of cooling an adverse im- mammoth herbivores on vegetation led to reduction

of tree species abundance and their survival in refugia only (in overdeepened river valleys). During warming periods tree species disseminated at surrounding areas. That is why broad-leaved and coniferous tree species with different abundance resided

together until the end of the Pleistocene, otherwise the forest cover was mixed [23, 38, 40, 82, 83].

Maps of deciduous and conifer tree species complexes for that period show absence of forest zones (Fig. 4).

Fig. 4. Distribution of boreal complex tree species (black triangle) and nemoral complex tree species (white circle) in Older, Early, Middle and Late Holocene

Based on paleontological data and specifics of fauna and flora, the vegetation cover of the discussed period can be considered a mosaic of forests, meadows and steppes. Moreover, dominance of pasture ecosystems was due not only to unfavorable climatic conditions for tree species (low temperatures), but mainly to suppression of woody vegetation by large herbivores of the mammoth fauna.

The population of mammoth complex key species and the mammoth itself became critical as a result of hunting activities in the end of the Pleistocene [30, 34, 84-87]. The mammoth either disappeared or its quantity was not enough to remain a key species at the most part of its area. It was shown by the data from early man sites, where fossils of dominant herd ungulates [88, 89] replaced previously dominated mammoth remains.

Besides, mammoth, woolly rhinoceros, cave lion and hyena, large and small cave bear [32, 66, 90] became extinct by the end of the late Wurm and early Holocene in Eastern Europe. Northern borders of saiga and red deer habitats moved down to the south [65, 70]. Giant deer became extinct about 7 000 BP in Ural mountains [91].

Extinction, shrinkage of the habitat of large herbivores of the mammoth complex resulted in spreading woody vegetation and reduction of areas of grass (pasture) ecosystem, which favored a slight warming [92]. The pioneers of afforestation were highly volatile tree species with seeds and fast turnover of generations: willow, birch, aspen and European pine. The pollen spectra of this period is marked by dominance of pine and birch [93, 94].

At the end of the Pleistocene replacement of grassland ecosystems by forests was initiated by primitive hunters who made a decisive contribution to reduction of area and population, and then extinction of mammoth and associated species: cave lion (Leo leospelaea), cave bear, cave hyena, giant deer, musk ox (Ovibos moschatus), prehistoric bison and woolly rhinoceros [19].

Later, at the late Pleistocene and in the beginning of the Holocene, the ocean transgression and the sea level rising lessened climate continentality. Most likely, the decline in population and composition of key species led to replacement of pasture ecosystems by forest ecosystems that began an irreversible process. Of course, it is particularly important in regional climate conditions. In the Far North, pasture ecosystems were gradually replaced by the tundra ecosystem, but the process took a very long time since the last mammoths became extinct about 3000 BP on Wrangel Island; and reindeer have survived to the present time on Arctic islands, and the musk ox - on North American Arctic islands. In a warmer and humid climate, these wood-pasture ecosystems were replaced by forest (including boreal) ecosystems. In the middle zone of Eastern Europe, including the territory of today's Moscow region, a number of species that were part of the pasture ecosystems was saved until the end, or almost to the end of the Holocene (more below).

The environmental change on vast territories caused the corresponding climate change. As a result, intensive replacement of the open steppes by wood vegetation dramatically reduced activity of summer anticyclones.

This has contributed to an increase in rainfall and water content, which in turn has proved to be very favorable for an increase in beaver population, which in return has enhanced water-irrigation processes. As a result, these replacements appeared to be more important than the activity of primitive

hunter-gatherers, the pasture type ecosystem was transformed, the northern allocation of steppe species pushed to the south and south-east.

Thus, since the end of the Late Pleistocene it began the process of change of keystone species (change of edificators - [87]): Giants and large herbivores species of mammoth complex stepped down a position of key species to tree species of modern forest zone. As a result of the slow start (which is quite natural in a fairly harsh climate), but steady replacement of pasture ecosystems for forest (detrital).

The early Holocene - Mesolithic (10 000-7000 BP) and the middle Holocene - Neolithic and the Bronze Age (7000-2500 BP)

The beginning of this period was characterized by a noticeable warming along with periodic cooling and warming [59, 92]. Pasture ecosystems continued to transform into detrital ecosystems due to the mammoth complex giants and large herbivores elimination. The intensity of this process was positively correlated with climate severity and humidity.

There are no data on the mammoth fauna presence to the East of the White Sea (the north of Eastern Europe) during the Holocene (except for survived brown bear, elk and reindeer), but to the west and to the south of their former area they survived in the Holocene as well.

At the beginning of the Holocene mammoths still persisted in the north-west of the Russian Plain (in Baltic region, Vologda region, Karelia and the Kola Peninsula), and in some places on the peripheral areas of its giant area in the recent past they lived even longer: up to 7 000 BP (the Yamal peninsula), to 3700 BP (Wrangell island) [66, 95-97]. Aurochs (Bos primigenius) were known up to the middle Holocene in the Lake Ladoga area [98], and in the regions to the south (or at least most of them) a set of species were found: wild horses, wild boars, giant deer, red deer and reindeer, deer, aurochs, bisons, saigas and musk oxen - were present throughout the early or even mid-Holocene [61, 62, 65, 99-106].

Among ungulates inhabiting the forests, wild boar expanded its area to the north and elk became more numerous in the Russian Plain, but disappeared from the Caucasus [107, 108]. Several species (wild horses, deer, elks, reindeer, aurochs) as well as mammoths penetrated to the north-west of Eastern Europe up to the Kola Peninsula in the early Holocene after degradation of the White Sea-Baltic Sea basin almost to its present size.

This opened opportunities of invasion to Fen-noscandia from the East for mammoths, musk oxen, reindeer and elks (species that lived in the

western part of this territory already in the late Pleistocene) [109, 110].

One cannot ignore that the destruction of the Paleolithic mammoth hunters' mode of life lead to a long environmental crisis for the population of Europe (and Eurasia as a whole): the number and density of Mesolithic sites drastically reduced [88, 89, 111].

That crisis was overcome only in the Neolithic period [112], when the spread of the producing economy (agriculture and animal domestication originated in more southern areas) effectively changed the very nature of human impacts on natural ecosystems. It should be taken into account that the extent of that impact increased gradually. That is why a number of species that were part of the Pleistocene mammoth fauna were preserved on the analyzed territory until the middle or even the late Holocene.

The process of transformation of pasture ecosystems by closed forest ecosystems was started by pioneer species (pine, aspen etc.) characterized by relatively fast expansion [39, 52], later replaced by key species of dark coniferous and broad-leaved trees (spruce, fir, oak, beach etc.). Changes in the ratio of steppe-pasture and forest communities in favor of the latter initiated formation of forests on the major part of Eastern Europe except for the northern territories (the Ugra Peninsula, Kolguev island, Vaigach island and South island of Novaya Zemlya) occupied by tundra and forest tundra.

This process in turn helped increasing the number of forest animals: squirrel, beaver, brown bear, wild boar, elk and other ungulates that benefited from expansion of forests. In the early Holocene, as in the previous period, forests were mixed, combining conifers (spruce, fir) and broad-leaved (oak, linden, elm, and other) tree species almost on the entire territory (Fig. 4) [10, 23].

Later in the middle Holocene almost the entire territory of Eastern Europe was a mosaic of meadow-steppe and forest (coniferous and broad-leaved) zone with the meadow steppe formed by large herd herbivores, alternated with forested areas. There was no clear division into the taiga and deciduous forests; instead, there was a gradual decrease in the proportion of species of deciduous trees from the south to the north and the proportion of species of conifer trees in the opposite direction. Large herd herbivores: elk and reindeer, along with wild boar, red deer, deer, auroch, bison and wild horse, and sometimes saiga and marmot, coexisted in the southern part of the forming forest zone before the Iron Age till the Middle Ages, as proved by the osteological data. This allows us to reconstruct the ecosystem cover of this time as a mosaic

of forest patches, alternated with meadow and steppe areas of zoogenic origin [10].

Existence of grassland and forest communities and ecotones between them allowed sustainable existence of the key species of light-demanding trees such as oak, pine, Siberian larch. They were accompanied by subordinate light-demanding species of trees, bushes, dwarf shrubs and grasses.

At the same time fossil remains of beavers were found on the major part of the Eastern Europe forest zone [10]. It indicates that widespread water communities were formed due to beaver's construction activities. Beaver ponds on numerous streams and small rivers allowed existence of various animals, plants and other species in so-called "beaver landscapes". Widespread hydromorphic landscapes determined a high level of soil and air moisture [113]. Apparently this was one of the major reasons of spreading of dark coniferous species (spruce and fir) to the south and broad-leaved species to the north, embracing one meadow-steppe-forest (coniferous - broad-leaved) zone. In addition, prevalence of hydromorphic landscapes prevented the spread of fires. Subsequent differentiation of the meadow-steppe-forest (coniferous and broad-leaved) zone led to formation of the boreal (taiga) zone.

Thus, from the late Pleistocene to around middle Holocene, mainly due to destruction of key species of the mammoth complex, there was a significant transformation of the ecosystem cover of Eastern Europe: pasture ecosystems were replaced by detrital and pasture ecosystems with equal shares.

Producing economy (agriculture, cattle breeding and metal smelting) development in the middle Holocene became a powerful factor influencing the ecosystem cover (the Neolithic Revolution). It spread in Eastern Europe 6000-5500 BP and dominated on most of its territory during the Bronze Age (4600-3200 BP). The share of fossils of wild hoofed animals (bison, auroch, wild horse, etc.) reduced, while the share of livestock bones increased [99, 100], also the pollen analysis showed the presence of domesticated cereals and weeds [114-116], as proved by the osteological material.

Producing economy fundamentally changed the structure of the ecosystem cover. First of all, large herd ungulates and beavers disappeared mostly not because of direct persecution, but due to habitats transformation for producing purposes. Destruction of large ungulates resulted in disappearance of meadows and ecotones, essential for light-requiring tree species, all other light-demanding plant species and many animal species. The economic activity determined existence of key species directly (trees planting) or indirectly (plowing,

burning, grazing in forests, drainages, pond constructions, etc.). Only shade-tolerant tree species (deciduous trees, except oak species, spruce, cedar and fir), shade-tolerant bushes, shrubs, herbs and mosses were able to maintain a steady generation turnover without human assistance in such environment. Ecosystems of "shadow" coniferous-broad-leaved forests were formed, which nowadays have survived only in a small number of refugia in European Russia, in habitats not affected by significant anthropogenic transformations of the last few centuries and, therefore, mistakenly taken for natural forests [10, 12]. By the end of the middle Holocene slash-and-burn agriculture notably pushed the southern border of the forest zone to the north.

Elimination of beavers harshly reduced natural diversity of valley landscapes of small rivers and streams, affected the hydrological regime stability, previously supported by dams and beaver ponds. At the same time, this led to a fire danger increase in forests.

In the late Middle Holocene, expansion of nomadic cattle breeding in the south of Eastern Europe led to formation of steppe and semi-steppe zones, increased climate aridity and reduced the mixed character of flora and fauna. These were major steps in formation of modern zoning, including the boreal (taiga) zone, and had significant impact on macroclimate changes in Eurasia as a whole. Perhaps these were among the reasons of a climate instability increase in the second half of the Holocene [50, 92, 117, 118].

The Late Holocene (2500-0 BP) -The Iron Age and Middle Ages (2500-500 BP)

Habitats of key species of trees did not change significantly at the beginning of the late Holocene -in the early Iron Age (2500-1600 BP), as the palaeobotanical analysis shows. Broad-leaved and coniferous species coexisted on the major part of the forest zone just as in the Middle Holocene (Fig. 4). However, the quantitative assessment of the pollen share of different tree species in the pollen spectra showed a decline of the dark coniferous species share in the south and the broad-leaved share in the north [93, 94, 119-121], and an increase of pollen of Pinus sylvestris led to increased fire activity. This process was due not only to expansion of the steppe zone to the north and increased soil and air dryness because of anthropogenic aridization in the south of Eastern Europe, but also due to direct anthropogenic impacts. The most significant were the following: usage of oak for shipbuilding [119] and for industrial production of wood charcoal since

the beginning of XVIII century [122], and massive logging for a variety of other purposes [10].

At the same time, mainly as a result of slash-and-burn agriculture, the northern borders of broad-leaved tree species areas significantly retreated to the south. That marked formation of the modern taiga - a boreal forest zone, where broad-leaved tree species are absent. At the same time, specific pyrogenic forests with dominance of Scots pines were formed [123] on vast territories with sandy soils. Slash-and-burn agriculture followed by swidden and arable farming, grazing in the forest, collecting of litter and deadwood and other traditional forest management practices led to soil cover degradation on vast areas [15, 16]. Forest burning on its northern borders led to tundra expansion over the northern taiga and the forest tundra in the late Holocene [124, 125]. Anthropogenic factors and climate changes of the late Holocene acted concurrently in the north of the forest zone. These led to destruction (purification) of the forest zone and fostered expansion of boreal species and their complexes. This process is called "borealiza-tion" of the forest zone.

Despite the fact that human impacts on natural ecosystems and their components steadily increased and became more diverse during the Neolithic and the Bronze Age, yet some areas remained underdeveloped. Therefore, such species as musk ox (Scythian drawings, see: [104, 126]) and onager (Equus hemionus) lived in the southern steppes and Ural, wild horse lived in the Caspian region [127] up to the Iron Age. Wild auroch, bison and tarpan - wild horse [101, 102, 106, 128] still exist in the south of the modern forest zone. The tarpan remains were found on the territory of modern Moscow at the beginning of the Iron Age (completely exterminated in the XIX century) as well as wild boar, red deer and reindeer, roe deer [103]. Reindeer were spread more to the south, comparing to its actual area [99, 122, 129].

Commercial fur trade, primarily in beaver and sable, emerged at the beginning of the Iron Age, and, incidentally, hunting pressure on larger ("meat") animals - elk and bear - sharply increased. This was observed during the research of massive osteological materials, obtained while excavating Dyakov settlement (south of Moscow). The people of this settlement switched from natural economy in the early Iron Age (2500-1500 BP) over to commercial hunting in 300-200 BP. The composition of prey species changed as a result: tarpan, red deer, raindeer, roe deer completely disappeared, a little later - wild boar, too. Hunting for beavers, elks and brown bears dramatically increased according to the analyzed remains [18, 103].

Naturally this process developed unevenly in different regions of Eastern Europe. Despite its huge area equaling almost to the entire Palearctic, beavers were exterminated everywhere, including the most remote regions of Eastern Siberia by the late Middle Ages [130].

Thus, the changes in tree species and fauna composition in the Late Holocene which started in the Middle Holocene led to a split of the united steppe-meadow-forest (coniferous and broad-leaved) zone into two fundamentally different community groups [131]:

(1) communities, capable of supporting itself developing spontaneously ("shadow" forests), that formed the forest zone as is, and (2) communities, requiring permanent anthropogenic impacts for maintenance (floodplain and upland meadows, meadow steppes, forest of light-requiring tree species: birch, scotch pine, larch, oak).

The traditional economy was evolving over a long time and in some forms was similar to natural processes (e.g. livestock grazing in the forest, construction of dams on small rivers for mills, etc.), so it helped supporting the ecosystem cover's heterogeneity.

However, at that point of time, the final step in formation of the modern zoning was made: a split of the forest zone of Eastern Europe into dark coniferous (boreal), coniferous and broad-leaved (boreal-nemoral) and broad-leaved (nemoral) forests, caused by anthropogenic impacts.

The Modern time (500 BP)

In recent centuries (since 18th, but especially in 19th and 20th centuries) further transformation of the ecosystem cover of Eastern Europe has been driven by land-use change and industrial development [10]. At that time, such species as auroch, bison, tarpan disappeared; areas of all large mammals, beaver and others decreased. Populations of some species have been restored during last decades: the beaver population has been restored due to restoration activities and further spontaneous dissemination, populations of wild boar and roe deer have been restored mostly due to urbanization and consequential land abandonment in rural areas.

Due to intensive agricultural development and timber harvesting, nemoral (broad-leaved) and nemoral-boreal (mixed broad-leaved and coniferous) forests have virtually merged into a single zone [132]. Small-leaved forests on clay soils and planted pine forests on sandy soils have alternated with agricultural lands. At the same time, forests with key species dominance have covered small areas [10].

However, oak was registered in the lower part of the Northern Dvina river even before the beginning of the 18th century [120]; hornbeam was registered to the north up to Valdai lowland [119] and elm was registered up to Obdorsk (now the town of Salekhard) [121] till the end of the 18th century.

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The boreal (taiga) forest zone finally became isolated inside the forest zone due to multiple human-induced fires, rural land abandonment because of inefficiency of agricultural activities and a population decrease. A mosaic of pyrogenic and weed grassland communities of different ages from young pine stands and birch forests to spruce and spruce-fir forests was formed. A substantial part of grassland ecosystems, supported in boreal forests by human activities since the middle - late middle Holocene, disappeared during the last one or two centuries due to land-use changes (agricultural activities including a livestock grazing decrease) and a catastrophic decline of rural population.

Most of the modern taiga forest ecosystems are at the early succession stages with pioneer species of trees (pine, birch) or the first generation of late-succession trees (spruce, more rarely fir) and minimal species. The latter are spruce and spruce-fir forests of green moss, green moss with dwarf shrubs and small boreal herbs (Oxalis acetosella).

These most widespread types of East European dark coniferous forests [20, 133] were formed and supported by human activities [10], and, unfortunately, are often seen as natural forests.

However, the analysis of modern distribution of nemoral and boreal shrubs and herbs, as well as presence of ephemeroids in the refugium [80] indicates that the original type of modern boreal forests is boreal-nemoral forests (Fig. 5).

It is in contemporary history, when such species as auroch, bison, tarpan disappeared, and areas of all large mammals, beaver and some other species decreased (populations of some species have been restored during last decades due to restoration activities).

The main trends of teriofauna transformation since the late Wurm to the present are the following:

1. Loss of habitats for many species (primarily, the largest and most actively hunted animals);

2. Extinction of some animal species (totally or within the Palearctic);

3. The single fauna was split up in space into faunas of tundra, forests and steppes. It is significant that the extinction rate of the Pleistocene the-riofauna species was exponential, continuing at the present time (Fig. 6). This process will continue for a long term, unless appropriate and extraordinary measures are taken, as proved by the available data [134].

Fig. 5. Modern distribution of boreal and nemoral complex of grass and shrubs (Lipmaa, 1938) (boreal - white triangle, nemoral - grey circle). The upper line shows north border of nemoral grass species, the line on the south shows border of boreal grass and shrubs species

The proposed model reconstruction shows that the main factor in formation and development of the vegetation cover of Eastern Europe, including boreal forests during the Holocene, was and is human land-use activities. It comes out as follows:

(1) key species areas direct move due to species extermination on some areas,

(2) key species areas indirect move due to eco-topes and local climate changes, primarily aridiza-tion in the south of the forest zone and its borealization in the north,

(3) destruction of functional links between key and indicator species, that provided stable digenesis in populations of species of different trophic groups.

The composition and structure of the most wide-spread types of forest communities (including boreal forests with trees' key species dominance) reflect traditional land-use practices, which were common at least during the lifetime of the current trees generation or a bit earlier.

The origin of the modern boreal zone of Eurasia (the Eurasian taiga)

The analysis of area changes of key species of animals and plants since the late Pleistocene to the present led to the concept of the dominant role of human activity in formation of the modern bo-

real zone of Eastern Europe. From this perspective it is advisable to refer to the hypothesis of the origin of the Eurasian taiga (boreal forest) in gen-

eral. Since the origin of taiga is well studied [2, 3, 5, 6, 38, 40] we confine this list to the most important ones.

Fig. 6. Extinction rate (number of extinct species during one thousand year) during Pleistocene up to the present

The discussion on the origin of the modern taiga includes the following key issues:

1) what was the initial type of vegetation [3, 5, 6, 27, 135];

2) does the boreal forest of autochtonous or al-lochthonic origin have any relation to the current territory of Eurasia and North America?

Neogene forests with rich flora of trees that prevailed on the territory of Northern Eurasia till almost the end of the Pliocene should be considered a natural type according to many authors [5, 38, 40, 136, 137]. Namely, these forests were the initial condition in formation of the modern forest cover of Northern Eurasia. Generic complexes of broad-leaved and coniferous trees, which compose the modern dendroflora of Northern Eurasia, were founded in Neogene forests.

V. P. Grichuk [40] described the main steps of formation of the modern nemoral and boreal floras from the Neogene flora. These floras were finally formed by the Upper Pleistocene [40] .There was a gradual depletion of generic complexes during the process of formation of the nemoral and boreal floras. For example, V. P. Grichuk allocated 30 generic complexes representing four geographic groups (Table 3) in the center of the Russian Plain in the end of the Pliocene. Only 20 of them remained in the Early Pleistocene, 15 in the Middle Pleistocene - and 12 complexes of circum-boreal groups remained in the Holocene. Simultaneously, the number of species in each generic complex significantly reduced. However, the process of dendro-flora depletion was gradual, and the mixed nature of dendroflora of the Russian Plain persisted throughout the Pleistocene and most of the Holocene.

Table 3

Dendroflora of Late Cenozoic in Vyatsko-Kamsky historical floristic region (Grichyuk, 1989)

Group Species sp. Late Pliocene Pleistocene Holocene

early middle late

Panarctic Abies

Picea

Pinus

Betula

A Inns

Salix

Larix

Myrica - - - -

American - North Asian Corylus

Quercus

Ulmus

Acer

Tilia

Carpinus —

Ilex — - -

Fraxinus 1 1 -

Fagus -

Taxus - - - -

American Mediterranean - Asian Celtis - - - -

Pterocaria - -

Juglans - -

Rhus - - -

Castanea - - -

Ostrya — — — —

American - East Asian Tsuga - - - -

Morus — — — —

Di er villa - - - -

Carya — — — —

Chamaecyparis - - - -

Liriodendron - - - -

Number of genera 30 20 15 14 12

Given short distances of late succession tree seeds dispersal: from 200 to 1000 meters over the lifetime of one generation [39, 138, 139], it should be recognized that almost continuous existence of that unique flora was possible only with a sufficient number of closely-spaced refugia, where tree species were preserved during adverse periods in the Pleistocene. The possible existence of refugia and the age thereof were repeatedly discussed in literature [138, 140, 141]. Recently, a valid evidence of refugia allocation in Eastern Europe during the late glacial maximum has been gained, based on the statistically reliable palynological data [82, 83]. The presence of these refugia determined quick dissemination of key species of trees in the early Holocene.

Recognition of a possibility of continuous transformation of Neogene flora in Northern Eurasia suggests that the taiga (boreal forest) is autoch-

thonous in Eurasia and North America, occupied thereby nowadays.

The assumption that taiga is of allochthonous origin, as pointed out by V. B. Sochava [2], is largely determined by the characteristics of the modern taiga, which were considered a result of the genesis of the ancient type of vegetation. If we consider modern pyrogenic dark coniferous forests [9], formed by humans in the Late Holocene, as a model of natural taiga [3], then it is quite difficult to find its origin from the Neogene flora. The hypotheses of its allochthonous origin tried to explain this: the area around the North Pole [135], an ancient land near the Bering Sea [142], the mountains of Palearctic South [3] were considered the original vegetation.

The boreal forest was seen as a younger formation in Circumpolar and Bering hypotheses, and development of the taiga landscape was interpreted as a

moving of existing species complexes from north to south. In the mountain hypothesis, the taiga was seen as an ancient formation, formed simultaneously with the Neogene vegetation or even earlier. Tolmachev [3] proved the antiquity of the taiga forest by a significant age of boreal herbs species.

Presence of keystone species (similar to Picea sp.) and associated boreal species of herbs and shrubs [3] in Neogene forests make it possible to assume that these mixed (coniferous - deciduous) forests gave place for successful coexistence of boreal and nemoral species. It is confirmed by forest refugia, where ephemeroids and other nemoral herbs species survive under the cover of dark coniferous trees [80].

If coniferous-broad-leaved nemoral-boreal forests of the Far East [2, 137] and the Caucasus [1]

are considered as natural ones (least disturbed taiga forests), then the hypothesis o fautochthonous origin of the modern taiga from Neogene forests due to gradual climate changes since the late Pliocene to the late Pleistocene is quite legitimate.

Examining the animal population of the late Pliocene allows assuming that the original Neogene mixed coniferous-broad-leaved forests of Northern Eurasia had a structure similar to modern forests.

The analysis of the number of large and very large herbivores (key species of grassland ecosystems) genera, which formed the Palearctic teriofau-na since the Pliocene to the present, demonstrates that Neogene forests were inhabited by rich fauna of large and very large mammalian herbivores (Fig. 7).

Fig. 7. Dynamics of number of genera from Pliocene up to the present

Most of the genera and species of this fauna inhabited savannas, steppes and forest steppes and many of them were key species of grassland ecosystems. Therefore, the Pliocene landscapes structurally and physiognomically to a greater extent resembled modern African savannas, than modern coniferous-broad-leaved forests of the Far East. Transformation of this fauna from the Pliocene to the present had a clear tendency to exhaustion: 37 genera inside and 24 genera outside the Palearctic survived out of 195 genera (mostly Proboscidea and Ungulates). Moreover, the extinction rate increased exponentially during the Holocene.

For grassland ecosystems the loss of the role of key species by large and giant herbivores was a crucial step in the irreversible transformation of fauna since the final Paleolithic to the late Holo-cene (in various regions the crisis was in different

time, in African savannas it happened only over a century ago). Firstly, it was due to species extermination and consequential reduction of its abundance below the critical level of sustainable generation turnover in populations. After that, further transformation of grassland ecosystems became autogenetic, its effects have amplified exponentially in the modern time and have been intensified by a variety of anthropogenic factors. Thus, the debate about the origin of the modern Eurasian taiga (boreal forest zone) switched into the study of the history of conversion of Neogene savanna forests by human activities.

The analysis of the dynamics of tree key species' paleoareas and data on the composition and structure of the modern remnants of boreal forests [80, 143] show that the coniferous-broad-leaved forest zone without the modern boreal forests (tai-

ga) zone could cover the major part of Eastern Europe (supposing only the climate-caused changes of Neogene forests). The anthropogenic factor since the late Pleistocene to the present, as the most powerful factor at different scales (from local to global) has determined formation of the boreal forest zone, consisting of succession communities, the composition and structure of which reflect different types of human activities over the last centuries.

The image of the modern taiga is very different from the reconstructed image of Neogene forests and their derivatives in the Far East and the Caucasus, so it is impossible to consider development stages of a single vegetation type (or single biome) without analyzing anthropogenic changes. This fact apparently fostered the hypothesis of taiga's allochthonous origin.

Paleobiological reconstruction of the teriofauna and denroflora since the late Pliocene to the present allows assuming that the initial vegetation type for boreal forests was Pliocene coniferous-broad-leaved savanna-looking forests of Northern Eurasia, where large herbivores affected biota the most. The ratio between key tree and animal species shows its fundamental difference from modern coniferous-broad-leaved forests of the Far East, which previously were seen as the Eurasian boreal forests (the Eurasian taiga) origin.

Conclusion

This study allows to offer a sequence of formation and development stages of the Eastern European taiga (boreal forest):

1. The original type - mixed coniferous-broad-leaved savanna-looking forests of Northern Eurasia with rich dendroflora (over 30 generic complexes on the Russian Plain) and rich megafauna (around 100 genera), which included forest and grassland ecosystems (the Pliocene).

2. Refugia of periodically impoverishing coniferous-broad-leaved forests in the forest-meadow-steppe vegetation cover were regulated by giant species of the mammoth complex (the Pleistocene).

3. The meadow/coniferous-broad-leaved forest vegetation was regulated by large herd ungulates, beavers and trees (the Middle Holocene).

4. The forest vegetation split into boreal (taiga), nemoral-boreal and nemoral zones as a result of human activities. Formation of the modern boundaries of the taiga and development of the taiga ecosystems preserved in refugia (first half of the Late Holocene).

5. The anthropogenically caused image of the modern East European taiga is a dominating complex of light and dark coniferous successional communities. Despite a wide distribution, these forests are characterized by their internal imbalances: very poor species composition of plants and animals, monodominant, with tendency for destruction by insects and fungi.

Financial support

Investigations were partially supported by the RFBR grant 16-16-04-00395

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