Actualistic approaches to interpreting the role of biological decomposition in microbial preservation

IF 2.7 2区 地球科学 Q2 BIOLOGY
Geobiology Pub Date : 2021-10-11 DOI:10.1111/gbi.12475
Ashley Manning-Berg, Tara Selly, Julie K. Bartley
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引用次数: 3

Abstract

Taphonomic processes, especially post-mortem biological decomposition, act as crucial controls on the microbial fossil record. Information loss during the fossilization process obscures interpretation of ancient microbial ecology and limits our view of preserved ecosystems. Conversely, taphonomic information can itself provide insight into fossilization pathways and processes. This information-gain approach requires specific attention to taphonomic patterns in ancient assemblages and robust modern analogue data to serve as points of reference. In this study, we combine experimental taphonomy with decomposition models in order to constrain taphonomic hypotheses regarding Proterozoic microfossil assemblages. Several filamentous and coccoidal prokaryotic and eukaryotic phototrophs were evaluated for taphonomic pattern over the course of a short (~100 days) decomposition experiment. In parallel, simple numerical models were constructed to explain potential taphonomic pathways. These analogue data were then compared to two Mesoproterozoic fossil assemblages, the ~1.5 Ga Kotuikan Formation, Siberia, and the ~1 Ga Angmaat Formation, Canada. Concordant with previous experiments and observations, our results suggest that sheath morphology is more persistent than cell/trichome morphology during early stages of decomposition. These experiments also suggest that taphonomic change in cell morphology may follow one of several trajectories, resulting in distinct taphonomic endpoints. Model output suggests two categories of underlying mechanism and resultant taphonomic trajectory: (1) uniform decomposition, resulting in a low overall taphonomic grade and poor preservation, and (2) faster decomposition of structurally compromised individuals, producing a final population with better overall preservation of very few individuals. In this experiment, cells of coccoidal organisms exhibit the first pattern and trichomes of filamentous organisms and some sheaths exhibit the second. Comparison with preserved microfossil assemblages suggests that differences in taphonomic pattern between parts of an assemblage could be useful in assessing taphonomic processes or degree of taphonomic loss in an entire assemblage.

解释生物分解在微生物保存中的作用的实际方法
埋藏过程,特别是死后的生物分解,对微生物化石记录起着至关重要的控制作用。化石过程中的信息丢失模糊了对古代微生物生态的解释,限制了我们对保存的生态系统的看法。相反,埋藏学信息本身可以提供对石化途径和过程的洞察。这种信息获取方法需要特别注意古代组合中的分音学模式和强大的现代模拟数据作为参考点。在本研究中,我们将实验埋藏学与分解模型相结合,以约束元古代微化石组合的埋藏学假设。在短时间(约100天)的分解实验中,对几种丝状和球状的原核和真核光养生物进行了分类模式评价。同时,建立了简单的数值模型来解释潜在的埋藏学途径。然后将这些模拟数据与西伯利亚~1.5 Ga Kotuikan组和加拿大~1 Ga Angmaat组两个中元古代化石组合进行了比较。与先前的实验和观察结果一致,我们的结果表明,在分解的早期阶段,鞘形态比细胞/毛状体形态更持久。这些实验还表明,细胞形态的缄默学变化可能遵循几种轨迹之一,导致不同的缄默学终点。模型的输出表明了两类潜在的机制和最终的语文学轨迹:(1)分解均匀,导致整体语文学等级较低,保存较差;(2)结构受损个体分解速度较快,产生整体保存较好的最终种群,个体数量很少。在本实验中,球状生物的细胞呈现第一种模式,丝状生物的毛状体和一些鞘呈现第二种模式。与保存完好的微化石组合的比较表明,组合各部分之间埋藏模式的差异可能有助于评估整个组合的埋藏过程或埋藏损失程度。
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来源期刊
Geobiology
Geobiology 生物-地球科学综合
CiteScore
6.80
自引率
5.40%
发文量
56
审稿时长
3 months
期刊介绍: The field of geobiology explores the relationship between life and the Earth''s physical and chemical environment. Geobiology, launched in 2003, aims to provide a natural home for geobiological research, allowing the cross-fertilization of critical ideas, and promoting cooperation and advancement in this emerging field. We also aim to provide you with a forum for the rapid publication of your results in an international journal of high standing. We are particularly interested in papers crossing disciplines and containing both geological and biological elements, emphasizing the co-evolutionary interactions between life and its physical environment over geological time. Geobiology invites submission of high-quality articles in the following areas: Origins and evolution of life Co-evolution of the atmosphere, hydrosphere and biosphere The sedimentary rock record and geobiology of critical intervals Paleobiology and evolutionary ecology Biogeochemistry and global elemental cycles Microbe-mineral interactions Biomarkers Molecular ecology and phylogenetics.
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