云南宜良上新世栎属植物研究及其古环境指示意义

doi:10.17520/biods.2022553

生物多样性 ›› 2022, Vol. 30 ›› Issue (11): 22553. DOI: 10.17520/biods.2022553

• 中国南方新生代植物多样性演化专题 • 上一篇下一篇

云南宜良上新世栎属植物研究及其古环境指示意义

戴静¹^,²^,^*(), 陈威兆¹, 金露露¹, 黄亮¹^,²^,³

1.云南大学地球科学学院地质系, 昆明 650500
2.自然资源部三江成矿作用及资源勘查利用重点实验室, 昆明 650051
3.云南省地质调查院, 昆明 650216

收稿日期:2022-09-23 接受日期:2022-11-30 出版日期:2022-11-20 发布日期:2022-12-01
通讯作者: 戴静
作者简介:* E-mail: daijing@ynu.edu.cn
基金资助:
国家自然科学基金(41962001);国家自然科学基金(41302013);云南省基础研究专项(202101AT070198);云南省科技厅?云南大学联合基金重点项目(2018FY001)

Fossil plants of Quercus from the Pliocene of Yiliang, Yunnan Province and their paleoenvironmental implications

Jing Dai¹^,²^,^*(), Weizhao Chen¹, Lulu Jin¹, Liang Huang¹^,²^,³

1. School of Earth Sciences, Yunnan University, Kunming 650500
2. Ministry of Natural Resources Key Laboratory of Sanjiang Metallogeny and Resources Exploration and Utilization, Kunming 650051
3. Yunnan Institute of Geological Survey, Kunming 650216

Received:2022-09-23 Accepted:2022-11-30 Online:2022-11-20 Published:2022-12-01
Contact: Jing Dai

摘要/Abstract

摘要：

栎属(Quercus)植物叶片化石在新生代地层中分布普遍, 对亚热带常绿阔叶林具有重要的指示意义。本文对采自云南省宜良县上新统茨营组中的栎属植物叶片化石进行角质层结构分析, 结合叶形态特征, 系统描述了4种栎属植物: 阔叶栎(Quercus latifolia)、线叶栎(Q. scottii)、楔基栎(Q. simulata)和黄毛青冈相似种(Q. cf. delavayi)。通过对比化石和现生植物的叶形态和角质层特征, 本文认为叶片形状、叶基和叶尖特征、二级脉数量、表皮细胞和垂周壁特征、气孔大小和形状、气孔密度、毛基类型、形态和分布情况可以作为区分不同种类的特征, 但是不能只考虑其中的一个因素, 应该综合这些特征作为判断依据。结合宜良植物群中其他化石资料认为, 包括壳斗科柯属(Lithocarpus)、栲属(Castanopsis)以及樟科、榆科、木兰科等在内的植物, 代表了以栎属青冈组为优势树种的半湿润常绿阔叶林。宜良植物群与同时期相近纬度的植物群相比, 植被类型相似, 但是落叶成分较少。宜良植物群中的线叶栎、楔基栎和阔叶栎同晚始新世的线叶栎以及早中新世的楔基栎和阔叶栎相比, 形态并未发生大的变化, 与现生植物也非常相似, 进一步说明云南现代常绿阔叶林的主要成分来自于古老植物的承袭, 没有发生较大的改变。

关键词: 栎属, 角质层, 常绿阔叶林, 上新世, 云南

Abstract

Aims: Fossil leaves of the genus Quercushave been widely reported from the Neogene. However, many fossil species were previously named without epidermal features. The present specimens from the Pliocene Ciying Formation in Yiliang, Yunnan Province provide detailed information about cuticular features, which can be useful for understanding the morphological variation at the genus and species level. Moreover, we explored the evolution of the evergreen broad-leaved forest in Yunnan Province, of which the genus Quercusis still the dominant element.

Methods: We observed the cuticular characteristics of the specimens using standard maceration and mounted it in glycerol on glass slides. By comparing leaf physiognomy and cuticular characteristics with previously reported fossil species and extant leaves, the present specimens were identified at the species level, containing three extinct and one existing species. Combined with else fossil plants collected from the Pliocene Ciying Formation, the vegetation form of Yiliang flora was recognized and compared with other floras of the same age in Yunnan Province.

Results: We systematically described leaf physiognomy and cuticular characteristics of four species of the genus Quercus Q. scottii, Q. simulata, Q. latifolia, and Q. cf. delavayi. The present Q. cf. delavayiwas similar to Q. praedelavayi†, Q. tenuipilosa† and living species Q. delavayi in leaf morphology and epidermal structures except for the trichome base densities. The compound trichome bases densely occurring in the advanced veins may be related to a defense function. The nearest living relative of the studied fossils were assigned based on morphological similarity. The fossil components indicated a semi-humid evergreen broad-leaved forest existed in the Pliocene of Yiliang area, which was dominated by Quercus sect. Cyclobalanopsis.The vegetation form was similar to the floras distributed in low-middle latitudes, rather than in middle-high latitude areas. The morphological characteristics of the present fossils Q. scottii, Q. simulata and Q. latifolia were similar to the Q. scottii of the late Eocene, Q. simulataand Q. latifolia of the Miocene, respectively, and all of them matched the nearest living relative species well. This implies that the dominant elements of the evergreen broad-leaved forest were inherited from the distant ages without great variation.

Conclusion: By analyzing leaf physiognomy and epidermal features, we determined that the present specimens belong to four species of the genus Quercus (Q. scottii, Q. simulata, Q. latifolia, and Q. cf. delavayi) and the most useful features for distinguishing among specimens are leaf shape, leaf base and apex shape, number of secondary veins, epidermal cells and anticlinal walls, stomatal size and frequency, trichome base type and density. However, of these characteristics cannot be used alone. The distribution and main components of evergreen broad-leaved forests in Yunnan have not changed greatly since the Cenozoic, which could be related to the complex topography and diversified environment of Yunnan Province.

Key words: Quercus, cuticle, evergreen broad-leaved fores, Pliocene, Yunnan

戴静, 陈威兆, 金露露, 黄亮 (2022) 云南宜良上新世栎属植物研究及其古环境指示意义. 生物多样性, 30, 22553. DOI: 10.17520/biods.2022553.

Jing Dai, Weizhao Chen, Lulu Jin, Liang Huang (2022) Fossil plants of Quercus from the Pliocene of Yiliang, Yunnan Province and their paleoenvironmental implications. Biodiversity Science, 30, 22553. DOI: 10.17520/biods.2022553.

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链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2022553

https://www.biodiversity-science.net/CN/Y2022/V30/I11/22553

图/表 5

图1 阔叶栎(1?4)和线叶栎(5?10)叶片特征。9可见具齿部分二级脉伸达齿尖, 10可见全缘部分二级脉弧曲向前。比例尺 = 1 cm。

Fig. 1 Leaf characteristics of Quercus latifolia (1?4) and Q. scottii (5?10). 9, Secondary vein extended to the tooth tip; 10, Secondary vein curved forward at the entire margin. Scale bars = 1 cm.

图2 楔基栎(1?6)和黄毛青冈相似种(7?16)叶片特性。14?16可见二级脉伸达齿尖。比例尺 = 1 cm。

Fig. 2 Leaf characteristics of Quercus simulata (1?6) and Q. cf. delavayi (7?16). 14?16, Secondary vein extended to the tooth tip. Scale bars = 1 cm.

图3 阔叶栎(1?5)和线叶栎(6?10)表皮特征以及叶表面附着的花粉(11?12)。1: 叶脉细胞和毛基; 2: 下表皮, 可见单细胞和多细胞毛基; 3: 上表皮细胞形态; 4: 下表皮细胞和气孔形态; 5: 多细胞复合毛基。6: 上表皮细胞形态; 7: 多细胞复合毛基; 8: 叶脉细胞长矩形, 可见椭圆形单细胞毛基; 9?10: 下表皮细胞形状不规则, 气孔密集分布于网眼内。1?2、10?12比例尺 = 50 μm; 3?8比例尺 = 25 μm; 9比例尺 = 100 μm。

Fig. 3 Cuticular characteristics of Quercus latifolia (1?5) and Q. scottii (6?10), and attached pollen on the leaf surface (11?12). 1, Epidermal cells and trichome bases on the leaf veins; 2, Unicellular and multicellular trichome bases on the abaxial epdermis; 3, Adaxial epidermal cells pentagons to hexagons; 4, Abaxial epidermal cells and stomata; 5, Compound trichome bases. 6, Adaxial epidermal cells quadrilateral to Pentagons or nearly circular; 7, Compound trichome bases; 8: Unicellular trichome bases on the leaf vein; 9?10, Abaxial epidermis, stomata densely distributed in the meshwork. 1?2, 10?12, Scale bar = 50 μm; 3?8, Scale bar = 25 μm; 9, Scale bar = 100 μm.

图4 楔基栎(1?5)和黄毛青冈相似种(6?10)表皮特征以及叶表面附着的花粉(11?12)。1: 上表皮; 2: 叶脉细胞和毛基; 3: 上表皮细胞; 4: 下表皮, 气孔分布于网眼内; 5: 多细胞复合毛基。6: 上表皮细胞, 垂周壁明显加厚; 7: 叶脉细胞和毛基; 8: 下表皮, 细胞较密集分布于网眼内; 9: 下表皮, 可见单细胞和多细胞复合毛基; 10: 复合毛基。1、9比例尺 = 100 μm; 2?8比例尺 = 50 μm; 10?12比例尺 = 25 μm。

Fig. 4 Cuticular characteristics of Quercus simulata (1?5) and Q.cf. delavayi (6?10), and attached pollen on the leaf surface (11?12). 1, Adaxial epidermis; 2, Epidermal cells and trichome bases on the leaf veins; 3, Adaxial epidermal cells; 4, Stomata distributed in the meshwork; 5, Compound trichome bases. 6, Adaxial Epidermal cells, with obviously thicken anticlinal walls; 7, Trichome bases on the leaf vein; 8, Abaxial epidermis, stomata densely distributed in the meshwork; 9, Abaxial epdermis, with unicellular and multicellular compound trichome bases; 10, Compound trichome base. 1, 9, Scale bar = 50 μm; 2?8, Scale bar = 50 μm; 10?12, Scale bar = 25 μm.

图5 扫描电镜下黄毛青冈相似种(1?5)、楔基栎(6?7)和线叶栎(8?9)表皮特征以及叶表面附着的花粉(10?12)。1: 下表皮脉络形态; 2、5: 气孔器形态; 3: 单细胞毛基; 4: 表面蜡质层。6: 表面蜡质层; 7: 多细胞复合毛基。8: 多细胞复合毛基环形; 9: 单细胞毛基。1比例尺 = 100 μm; 2?3、10?12比例尺 = 10 μm; 4?5、8?9比例尺 = 20 μm; 6比例尺 = 50 μm。

Fig. 5 Cuticular characteristics of Quercus cf. delavayi (1?5), Q. simulata (6?7) and Q. scottii (8?9), and attached pollen on the leaf surface under the SEM. 1, Morphology of abaxial epidermis; 2, 5, Shape of stomata; 3, Unicellular trichome bases; 4, Epidermal wax. 6, Epidermal wax; 7, Compound trichome bases; 8, Compound trichome bases; 9, Unicellular trichome bases. 1, Scale bar = 100 μm; 2?3, 10?12, Scale bar = 10 μm; 4?5, 8?9, Scale bar = 20 μm; 6, Scale bar = 50 μm.

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云南宜良上新世栎属植物研究及其古环境指示意义

Fossil plants of Quercus from the Pliocene of Yiliang, Yunnan Province and their paleoenvironmental implications

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