Chemotaxonomic patterns of vegetation and soils along altitudinal transects of the Bale Mountains, Ethiopia, and implications for paleovegetation reconstructions – Part II: lignin-derived phenols and leaf-wax-derived n-alkanes

B. Lemma, B. Mekonnen, B. Glaser, W. Zech, S. Nemomissa, T. Bekele, L. Bittner, M. Zech
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引用次数: 12

Abstract

Abstract. Erica is a dominant vegetation type in many sub-afroalpine ecosystems, such as the Bale Mountains in Ethiopia. However, the past extent of Erica is not well known and climate versus anthropogenic influence on altitudinal shifts are difficult to assign unambiguously, especially during the Holocene. The main objective of the present study is to chemotaxonomically characterize the dominant plant species occurring in the Bale Mountains using lignin phenols and n-alkane biomarkers and to examine the potential of those biomarkers for reconstructing vegetation history. Fresh plant material, organic layer and mineral topsoil samples were collected along a northeastern and a southwestern altitudinal transect (4134–3870 and 4377–2550 m a.s.l., respectively). Lignin-derived vanillyl, syringyl and cinnamyl phenols were analyzed using the cupric oxide oxidation method. Leaf-wax-derived n-alkanes were extracted and purified using Soxhlet and aminopropyl columns. Individual lignin phenols and n-alkanes were separated by gas-chromatography and detected by mass spectrometry and flame ionization detection, respectively. We found that the relative contributions of vanillyl, syringyl and cinnamyl phenols allow us to chemotaxonomically distinguish contemporary plant species of the Bale Mountains. Erica in particular is characterized by relatively high cinnamyl contributions of >40 %. However, litter degradation strongly decreases the lignin phenol concentrations and completely changes the lignin phenol patterns. Relative cinnamyl contributions in soils under Erica were <40 %, while soils that developed under Poaceae (Festuca abyssinica) exhibited relative cinnamyl contributions of >40 %. Similarly, long-chain n-alkanes extracted from the leaf waxes allowed for differentiation between Erica versus Festuca abyssinica and Alchemilla, based on lower C31 ∕ C29 ratios in Erica. However, this characteristic plant pattern was also lost due to degradation in the respective O layers and Ah horizons. In conclusion, although in modern-day plant samples a chemotaxonomic differentiation is possible, soil degradation processes seem to render the proxies unusable for the reconstruction of the past extent of Erica on the Sanetti Plateau, Bale Mountains, Ethiopia. This finding is of high relevance beyond our case study.
埃塞俄比亚贝尔山脉沿海拔样带植被和土壤的化学分类模式及其对古植被重建的意义。第2部分:木质素衍生的酚类和叶蜡衍生的正构烷烃
摘要埃里卡是许多亚非洲高山生态系统的主要植被类型,如埃塞俄比亚的贝尔山脉。然而,埃里卡过去的范围并不为人所知,气候与人为对海拔变化的影响很难明确地分配,特别是在全新世期间。本研究的主要目的是利用木质素酚类和正构烷烃类生物标志物对贝尔山脉的优势植物物种进行化学分类,并研究这些生物标志物在重建植被历史方面的潜力。在海拔高度分别为4134 ~ 3870 m和4377 ~ 2550 m的东北和西南样带采集了新鲜植物、有机层和矿物表土样品。分别)。采用氧化铜氧化法对木质素衍生的香兰基、丁香基和肉桂基酚进行了分析。用索氏柱和氨基丙基柱对叶蜡衍生的正构烷烃进行了提取和纯化。用气相色谱法分离木质素酚类化合物,用质谱法和火焰电离法检测木质素酚类化合物。我们发现香草基、丁香基和肉桂基酚的相对贡献使我们能够在化学分类上区分贝尔山当代植物物种。尤其是艾丽卡,肉桂基的贡献相对较高,> 40%。而凋落物的降解则使木质素酚浓度显著降低,并彻底改变了木质素酚的形态。在Erica土壤中肉桂基的相对贡献为40%。同样,从叶蜡中提取的长链正链烷烃可以区分埃里卡与羊茅和炼金术,基于埃里卡中较低的C31 / C29比率。然而,由于各O层和Ah层的退化,这种特征的植物格局也丧失了。总之,尽管在现代植物样本中,化学分类分化是可能的,但土壤退化过程似乎使这些替代指标无法用于重建埃塞俄比亚贝尔山脉Sanetti高原上Erica过去的范围。这一发现与我们的案例研究高度相关。
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