{"title":"亚洲新生代化石区系的生态和生物地理意义","authors":"Xiao-Yan Liu, S. Manchester","doi":"10.1111/jse.12488","DOIUrl":null,"url":null,"abstract":"This collection of articles highlights current paleobotanical research on the Paleogene and Neogene of Asia, following on a symposium held at the International Botanical Congress in Shenzhen, China in 2017, “Ecological and biogeographic implications of Asian Oligocene and Neogene fossil floras.” Fossil floras of this age, scattered across Asia, provide important data for assessing plant community response to changing topography and climate. During this time interval, from approximately 33.9 Ma to 2.58 Ma, the effects of rising mountains, oscillations of climate, and correlated changes in sea level have influenced development of the modern spatial pattern of plant diversity. The authors of this issue have used a variety of approaches to investigate different kinds of fossil plant remains including fruits, seeds, leaves, wood, and pollen to address questions of systematics, paleobiogeography, paleoecology, and climate change. During recent years, many new fossil floras have been investigated and various taxa have been described in detail (e.g., Huang et al., 2016; Quan et al., 2016; Yabe, 2017; Yabe & Nakagawa, 2018). Now is an appropriate time to gather the latest evidence of fossil records and paleoenvironmental data to discuss their ecological and biogeographic implications, thus to better understand mechanisms of biogeographic change. Asian fossil plant records are key to understanding patterns of plantmigration, radiation, and extirpation that have shaped present-day phytogeographic patterns in the Northern Hemisphere. Investigating the past biodiversity through geological time is critical to understand how this modern botanical richness formed (Popova et al., 2013; Huang et al., 2016; Yabe, 2017; Yabe & Nakagawa, 2018). We chose to focus the symposium on Oligocene and Neogene floras of Asia. The international stratigraphic community has largely abandoned the former recognition of the “Tertiary Period” in favor of the Paleogene and Neogene Periods; however, the conventional assignment of Oligocene epoch to the Paleogene makes the distinction between Paleogene and Neogene seem artificial because Oligocene vegetation shares more in common with the Neogene (Miocene through Pliocene) than with the Paleocene and Eocene vegetation. For this issue of JSE we have augmented the scope to include some contributions on Paleocene and Eocene plants. The articles herein fall under two overlapping themes: vegetation and climate assessed from fossil plant assemblages, and taxonomic and biogeographic history. Popova et al. (2019) document floristic change and continuity in western Siberian vegetation during the early Oligocene to earliest Miocene based on well-preserved fossil fruits and seeds. Based on the taxonomic identifications, the fossils were assigned to 26 plant functional types, including but not limited to C4 herbs, broad-leaved summer green arctic shrubs, broad-leaved evergreen warm temperate shrubs, broad-leaved evergreen xeric shrubs, needle-leaved evergreen boreal/temperate cold trees, drought-tolerant needleleaved evergreen trees, broad-leaved evergreen subtropical trees, broad-leaved summer green boreal/cold temperate trees, and aquatic components. The distribution of functional types was analyzed in a database comprising 66 carpofloras of Nikitin (2006). From these data, it can be concluded that temperatemesophytic, mixed conifer broad-leaved deciduous forest persisted in western Siberia throughout the Oligocene and earliest Miocene, supporting the concept of relatively stable climate conditions, without significant drying through this time interval in this region. The authors also detected an increase in taxonomic diversity, particularly concerning mesic herbs and deciduous trees and shrubs near the end of the Oligocene thatmight be related to increased precipitation and expansion of terrestrial habitats following retreat of the Paratethys sea. Yabe et al. (2019) present an informative and insightful overview of the paleobotanical history conifer genera that are presently endemic to eastern Asia, with emphasis on Oligocene and Neogene fossil floras of Japan and Korea. Six of the genera, namely Metasequoia, Glyptostrobus, Taiwania, Keteleeria, Pseudolarix, and Cunninghamia, occupied a wider range of environmental conditions in the past than their modern representatives. Their geographic distributions have shifted and/or receded since the late Miocene, possibly through habitat partitioning. They appear to have expanded their habitat toward warmer conditions during the midMiocene Climatic Optimum but then became restricted to warmer forest vegetation by the end of Pliocene. Cryptomeria and Thujopsis were found especially in floras of cooler temperate climate and they continued to maintain their range in the northern part of Japan where they are now endemic. During the late Miocene–Pliocene, the connection of the islands with the Asian continent functioned as a corridor for the dispersal of warm-adapted genera. Wu et al. (2019) report cupressaceous foliage from the early Oligocene of Guangdong Province, South China based on fossil foliage with well-preserved cuticle. Although there is a resemblance to foliage of the extinct mesophytic species of Tetraclinis salicornioides, known from attached cones and foliage in the Oligocene–Miocene of Europe and North America (Kva cek et al., 2000), the authors conclude that their leaves represent the extant genus Calocedrus, JSE Journal of Systematics and Evolution","PeriodicalId":101317,"journal":{"name":"JOURNAL OF SYSTEMATICS AND EVOLUTION","volume":"14 1","pages":""},"PeriodicalIF":3.7000,"publicationDate":"2019-03-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":"{\"title\":\"Ecological and Biogeographic Implications of Asian Cenozoic Fossil Floras\",\"authors\":\"Xiao-Yan Liu, S. 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The authors of this issue have used a variety of approaches to investigate different kinds of fossil plant remains including fruits, seeds, leaves, wood, and pollen to address questions of systematics, paleobiogeography, paleoecology, and climate change. During recent years, many new fossil floras have been investigated and various taxa have been described in detail (e.g., Huang et al., 2016; Quan et al., 2016; Yabe, 2017; Yabe & Nakagawa, 2018). Now is an appropriate time to gather the latest evidence of fossil records and paleoenvironmental data to discuss their ecological and biogeographic implications, thus to better understand mechanisms of biogeographic change. Asian fossil plant records are key to understanding patterns of plantmigration, radiation, and extirpation that have shaped present-day phytogeographic patterns in the Northern Hemisphere. Investigating the past biodiversity through geological time is critical to understand how this modern botanical richness formed (Popova et al., 2013; Huang et al., 2016; Yabe, 2017; Yabe & Nakagawa, 2018). We chose to focus the symposium on Oligocene and Neogene floras of Asia. The international stratigraphic community has largely abandoned the former recognition of the “Tertiary Period” in favor of the Paleogene and Neogene Periods; however, the conventional assignment of Oligocene epoch to the Paleogene makes the distinction between Paleogene and Neogene seem artificial because Oligocene vegetation shares more in common with the Neogene (Miocene through Pliocene) than with the Paleocene and Eocene vegetation. For this issue of JSE we have augmented the scope to include some contributions on Paleocene and Eocene plants. The articles herein fall under two overlapping themes: vegetation and climate assessed from fossil plant assemblages, and taxonomic and biogeographic history. Popova et al. (2019) document floristic change and continuity in western Siberian vegetation during the early Oligocene to earliest Miocene based on well-preserved fossil fruits and seeds. Based on the taxonomic identifications, the fossils were assigned to 26 plant functional types, including but not limited to C4 herbs, broad-leaved summer green arctic shrubs, broad-leaved evergreen warm temperate shrubs, broad-leaved evergreen xeric shrubs, needle-leaved evergreen boreal/temperate cold trees, drought-tolerant needleleaved evergreen trees, broad-leaved evergreen subtropical trees, broad-leaved summer green boreal/cold temperate trees, and aquatic components. The distribution of functional types was analyzed in a database comprising 66 carpofloras of Nikitin (2006). From these data, it can be concluded that temperatemesophytic, mixed conifer broad-leaved deciduous forest persisted in western Siberia throughout the Oligocene and earliest Miocene, supporting the concept of relatively stable climate conditions, without significant drying through this time interval in this region. The authors also detected an increase in taxonomic diversity, particularly concerning mesic herbs and deciduous trees and shrubs near the end of the Oligocene thatmight be related to increased precipitation and expansion of terrestrial habitats following retreat of the Paratethys sea. Yabe et al. (2019) present an informative and insightful overview of the paleobotanical history conifer genera that are presently endemic to eastern Asia, with emphasis on Oligocene and Neogene fossil floras of Japan and Korea. Six of the genera, namely Metasequoia, Glyptostrobus, Taiwania, Keteleeria, Pseudolarix, and Cunninghamia, occupied a wider range of environmental conditions in the past than their modern representatives. Their geographic distributions have shifted and/or receded since the late Miocene, possibly through habitat partitioning. They appear to have expanded their habitat toward warmer conditions during the midMiocene Climatic Optimum but then became restricted to warmer forest vegetation by the end of Pliocene. Cryptomeria and Thujopsis were found especially in floras of cooler temperate climate and they continued to maintain their range in the northern part of Japan where they are now endemic. During the late Miocene–Pliocene, the connection of the islands with the Asian continent functioned as a corridor for the dispersal of warm-adapted genera. Wu et al. (2019) report cupressaceous foliage from the early Oligocene of Guangdong Province, South China based on fossil foliage with well-preserved cuticle. 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引用次数: 2
摘要
本文集是继2017年在中国深圳举行的“亚洲渐新世和新近纪化石区系的生态和生物地理意义”国际植物学大会之后,对亚洲古近纪和新近纪古植物学研究的最新综述。这个时代的植物化石分布在亚洲各地,为评估植物群落对地形和气候变化的反应提供了重要数据。在33.9 ~ 2.58 Ma这段时间内,高山上升、气候波动和相关海平面变化影响了现代植物多样性空间格局的发展。本期作者采用多种方法研究了不同种类的植物化石,包括果实、种子、叶子、木材和花粉,以解决系统学、古生物地理学、古生态学和气候变化等问题。近年来,人们研究了许多新的化石区系,并对各种分类群进行了详细描述(如Huang et al., 2016;Quan et al., 2016;今年,2017;Yabe & Nakagawa, 2018)。现在是收集化石记录和古环境数据的最新证据,讨论其生态和生物地理意义,从而更好地了解生物地理变化机制的合适时机。亚洲植物化石记录是理解植物迁移、辐射和灭绝模式的关键,这些模式塑造了当今北半球的植物地理格局。通过地质时间调查过去的生物多样性对于理解这种现代植物丰富度是如何形成的至关重要(Popova et al., 2013;黄等人,2016;今年,2017;Yabe & Nakagawa, 2018)。我们选择以亚洲渐新世和新近纪植物区系为专题。国际地层学界在很大程度上放弃了以前对“第三纪”的认识,转而采用古近纪和新近纪;然而,将渐新世划归到古近纪的传统做法使古近纪和新近纪之间的区分显得有些人为,因为渐新世植被与新近纪(中新世至上新世)相比,与古新世和始新世植被有更多的共同之处。在这一期的JSE中,我们增加了一些关于古新世和始新世植物的文章。这里的文章分为两个重叠的主题:从化石植物组合评估植被和气候,以及分类和生物地理历史。Popova等人(2019)基于保存完好的水果和种子化石,记录了西伯利亚西部植被在渐新世早期至中新世早期的植物区系变化和连续性。在分类鉴定的基础上,将这些化石划分为26种植物功能类型,包括但不限于C4草本植物、阔叶夏季绿色北极灌木、常绿暖温带阔叶常绿灌木、常绿干旱阔叶常绿乔木、针叶常绿北方/温带寒带乔木、耐旱针叶常绿亚热带阔叶常绿乔木、阔叶夏季绿色北方/寒带乔木和水生成分。对Nikitin(2006) 66个carpoflora的功能类型分布进行了分析。从这些数据可以得出结论,在渐新世和中新世早期,西伯利亚西部的温生混合针叶阔叶落叶林持续存在,支持了该地区相对稳定的气候条件的概念,在此时间间隔内该地区没有明显的干燥。作者还发现了分类学多样性的增加,特别是在渐新世末期的仲叶草和落叶乔木和灌木方面,这可能与Paratethys海退缩后降水增加和陆地栖息地扩大有关。Yabe等人(2019)对目前东亚特有的古植物学历史针叶树属进行了信息丰富和深刻的概述,重点介绍了日本和韩国的渐新世和新近纪化石区系。其中水杉属、水杉属、台湾属、油杉属、pseudoolarix属和杉木属6个属在过去的环境条件范围比它们的现代代表更广。自中新世晚期以来,它们的地理分布已经转移和/或退缩,可能是由于栖息地的划分。它们似乎在中新世中期气候最佳时期向更温暖的环境扩展了栖息地,但在上新世末期,它们被限制在更温暖的森林植被中。柳杉属和土芥属在温带气候较冷的植物区系中被发现,它们在日本北部继续保持着它们的分布范围,现在在那里它们是地方性的。 中新世晚期至上新世,这些岛屿与亚洲大陆的连接处成为了暖适应物种扩散的通道。Wu et al.(2019)基于保存良好角质层的树叶化石,报道了广东早渐新世的柏科树叶。尽管与已灭绝的中生植物Tetraclinis salicornioides的叶子相似,该植物从欧洲和北美渐新世-中新世的附生球茎和叶子中得知(Kva cek et al., 2000),但作者得出结论,它们的叶子代表了现存的Calocedrus属,JSE Journal of Systematics and Evolution
Ecological and Biogeographic Implications of Asian Cenozoic Fossil Floras
This collection of articles highlights current paleobotanical research on the Paleogene and Neogene of Asia, following on a symposium held at the International Botanical Congress in Shenzhen, China in 2017, “Ecological and biogeographic implications of Asian Oligocene and Neogene fossil floras.” Fossil floras of this age, scattered across Asia, provide important data for assessing plant community response to changing topography and climate. During this time interval, from approximately 33.9 Ma to 2.58 Ma, the effects of rising mountains, oscillations of climate, and correlated changes in sea level have influenced development of the modern spatial pattern of plant diversity. The authors of this issue have used a variety of approaches to investigate different kinds of fossil plant remains including fruits, seeds, leaves, wood, and pollen to address questions of systematics, paleobiogeography, paleoecology, and climate change. During recent years, many new fossil floras have been investigated and various taxa have been described in detail (e.g., Huang et al., 2016; Quan et al., 2016; Yabe, 2017; Yabe & Nakagawa, 2018). Now is an appropriate time to gather the latest evidence of fossil records and paleoenvironmental data to discuss their ecological and biogeographic implications, thus to better understand mechanisms of biogeographic change. Asian fossil plant records are key to understanding patterns of plantmigration, radiation, and extirpation that have shaped present-day phytogeographic patterns in the Northern Hemisphere. Investigating the past biodiversity through geological time is critical to understand how this modern botanical richness formed (Popova et al., 2013; Huang et al., 2016; Yabe, 2017; Yabe & Nakagawa, 2018). We chose to focus the symposium on Oligocene and Neogene floras of Asia. The international stratigraphic community has largely abandoned the former recognition of the “Tertiary Period” in favor of the Paleogene and Neogene Periods; however, the conventional assignment of Oligocene epoch to the Paleogene makes the distinction between Paleogene and Neogene seem artificial because Oligocene vegetation shares more in common with the Neogene (Miocene through Pliocene) than with the Paleocene and Eocene vegetation. For this issue of JSE we have augmented the scope to include some contributions on Paleocene and Eocene plants. The articles herein fall under two overlapping themes: vegetation and climate assessed from fossil plant assemblages, and taxonomic and biogeographic history. Popova et al. (2019) document floristic change and continuity in western Siberian vegetation during the early Oligocene to earliest Miocene based on well-preserved fossil fruits and seeds. Based on the taxonomic identifications, the fossils were assigned to 26 plant functional types, including but not limited to C4 herbs, broad-leaved summer green arctic shrubs, broad-leaved evergreen warm temperate shrubs, broad-leaved evergreen xeric shrubs, needle-leaved evergreen boreal/temperate cold trees, drought-tolerant needleleaved evergreen trees, broad-leaved evergreen subtropical trees, broad-leaved summer green boreal/cold temperate trees, and aquatic components. The distribution of functional types was analyzed in a database comprising 66 carpofloras of Nikitin (2006). From these data, it can be concluded that temperatemesophytic, mixed conifer broad-leaved deciduous forest persisted in western Siberia throughout the Oligocene and earliest Miocene, supporting the concept of relatively stable climate conditions, without significant drying through this time interval in this region. The authors also detected an increase in taxonomic diversity, particularly concerning mesic herbs and deciduous trees and shrubs near the end of the Oligocene thatmight be related to increased precipitation and expansion of terrestrial habitats following retreat of the Paratethys sea. Yabe et al. (2019) present an informative and insightful overview of the paleobotanical history conifer genera that are presently endemic to eastern Asia, with emphasis on Oligocene and Neogene fossil floras of Japan and Korea. Six of the genera, namely Metasequoia, Glyptostrobus, Taiwania, Keteleeria, Pseudolarix, and Cunninghamia, occupied a wider range of environmental conditions in the past than their modern representatives. Their geographic distributions have shifted and/or receded since the late Miocene, possibly through habitat partitioning. They appear to have expanded their habitat toward warmer conditions during the midMiocene Climatic Optimum but then became restricted to warmer forest vegetation by the end of Pliocene. Cryptomeria and Thujopsis were found especially in floras of cooler temperate climate and they continued to maintain their range in the northern part of Japan where they are now endemic. During the late Miocene–Pliocene, the connection of the islands with the Asian continent functioned as a corridor for the dispersal of warm-adapted genera. Wu et al. (2019) report cupressaceous foliage from the early Oligocene of Guangdong Province, South China based on fossil foliage with well-preserved cuticle. Although there is a resemblance to foliage of the extinct mesophytic species of Tetraclinis salicornioides, known from attached cones and foliage in the Oligocene–Miocene of Europe and North America (Kva cek et al., 2000), the authors conclude that their leaves represent the extant genus Calocedrus, JSE Journal of Systematics and Evolution