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干旱环境下的生态系统多样性:来自伊比利亚东部晚白垩世的植物群及相关生物群。

Biodiversity of ecosystems in an arid setting: The late Albian plant communities and associated biota from eastern Iberia.

机构信息

Museo Geominero, Centro Nacional Instituto Geológico y Minero de España CN-IGME CSIC, Madrid, Spain.

School of Earth and Environment, Centre for Energy Geoscience, University of Western Australia, Crawley, Western Australia, Australia.

出版信息

PLoS One. 2023 Mar 2;18(3):e0282178. doi: 10.1371/journal.pone.0282178. eCollection 2023.

DOI:10.1371/journal.pone.0282178
PMID:36862709
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9980801/
Abstract

Deserts are stressful environments where the living beings must acquire different strategies to survive due to the water stress conditions. From the late Albian to the early Cenomanian, the northern and eastern parts of Iberia were the location of the desert system represented by deposits assigned to the Utrillas Group, which bear abundant amber with numerous bioinclusions, including diverse arthropods and vertebrate remains. In the Maestrazgo Basin (E Spain), the late Albian to early Cenomanian sedimentary succession represents the most distal part of the desert system (fore-erg) that was characterised by an alternation of aeolian and shallow marine sedimentary environments in the proximity of the Western Tethys palaeo-coast, with rare to frequent dinoflagellate cysts. The terrestrial ecosystems from this area were biodiverse, and comprised plant communities whose fossils are associated with sedimentological indicators of aridity. The palynoflora dominated by wind-transported conifer pollen is interpreted to reflect various types of xerophytic woodlands from the hinterlands and the coastal settings. Therefore, fern and angiosperm communities abundantly grew in wet interdunes and coastal wetlands (temporary to semi-permanent freshwater/salt marshes and water bodies). In addition, the occurrence of low-diversity megafloral assemblages reflects the existence of coastal salt-influenced settings. The palaeobotanical study carried out in this paper which is an integrative work on palynology and palaeobotany, does not only allow the reconstruction of the vegetation that developed in the mid-Cretaceous fore-erg from the eastern Iberia, in addition, provides new biostratigraphic and palaeogeographic data considering the context of angiosperm radiation as well as the biota inferred in the amber-bearing outcrops of San Just, Arroyo de la Pascueta and La Hoya (within Cortes de Arenoso succesion). Importantly, the studied assemblages include Afropollis, Dichastopollenites, Cretacaeiporites together with pollen produced by Ephedraceae (known for its tolerance to arid conditions). The presence of these pollen grains, typical for northern Gondwana, associates the Iberian ecosystems with those characterising the mentioned region.

摘要

沙漠是充满压力的环境,生物必须采取不同的策略才能生存,因为这里存在水分胁迫的情况。从晚白垩世阿尔比期到早白垩世赛诺曼期,伊比利亚的北部和东部是由乌特里利亚斯组沉积物代表的沙漠系统的所在地,该组沉积物中含有大量琥珀,其中有许多生物内含物,包括各种节肢动物和脊椎动物的遗骸。在马埃斯特雷萨盆地(西班牙东部),晚白垩世阿尔比期到早白垩世赛诺曼期的沉积序列代表了沙漠系统(前陆)的最远端,其特征是在靠近西部特提斯古海岸的地方,交替出现风成和浅海沉积环境,偶尔出现丰富的沟鞭藻孢囊。该地区的陆地生态系统多种多样,包含的植物群落与干旱的沉积学指标有关。以风传针叶树花粉为主的孢粉组合被解释为反映了来自内陆和沿海地区的各种类型的旱生林地。因此,蕨类植物和被子植物群落大量生长在湿沙丘间地和沿海湿地(临时到半永久性淡水/盐沼和水体)中。此外,低多样性的大型植物组合的出现反映了存在受海岸影响的环境。本文进行的古植物学研究是孢粉学和古植物学的综合研究,不仅可以重建伊比利亚东部中生代前陆的植被,还提供了新的生物地层学和古地理数据,考虑了被子植物辐射的背景以及在圣胡斯托、阿罗约德拉萨帕斯和拉霍亚(科尔特斯德阿雷纳索斯组内)含琥珀露头中推断出的生物群。重要的是,研究的组合包括 Afropollis、Dichastopollenites、Cretacaeiporites 以及麻黄科花粉(以耐受干旱条件而闻名)。这些花粉粒的存在,是典型的北方冈瓦纳特征,将伊比利亚的生态系统与上述地区的生态系统联系起来。

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How deep is the conflict between molecular and fossil evidence on the age of angiosperms?分子与化石证据在被子植物的时代问题上的冲突有多深?
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