Krings Wencke, Brütt Jan-Ole, Gorb Stanislav N
Department of Behavioral Biology, Institute of Cell and Systems Biology of Animals, Universität Hamburg, Martin-Luther-King-Platz 3, 20146, Hamburg, Germany.
Department of Mammalogy and Palaeoanthropology, Leibniz Institute for the Analysis of Biodiversity Change, Martin-Luther-King-Platz 3, 20146, Hamburg, Germany.
Front Zool. 2022 Jun 11;19(1):19. doi: 10.1186/s12983-022-00465-w.
The radula, a chitinous membrane with embedded teeth, is one important molluscan autapomorphy. In some taxa (Polyplacophora and Patellogastropoda) one tooth type (the dominant lateral tooth) was studied intensively in the last decades with regard to its mechanical properties, chemical and structural composition, and the relationship between these parameters. As the dominant lateral tooth is probably one of the best studied biological materials, it is surprising, that data on elements and mechanical properties of the other tooth types, present on a chiton radula, is lacking.
We provide data on the elemental distribution and mechanical properties (hardness and elasticity, i.e. Young's modulus) of all teeth from the Polyplacophora Lepidochitona cinerea (Linnaeus, 1767) [Chitonidae: Ischnochitonidae]. The ontogeny of elements, studied by energy-dispersive X-ray spectroscopy, and of the mechanical properties, determined by nanoindentation, was analysed in every individual tooth type. Additionally, we performed breaking stress experiments with teeth under dry and wet condition, highlighting the high influence of the water content on the mechanical behaviour of the radula. We thereby could determine the forces and stresses, teeth can resist, which were previously not studied in representatives of Polyplacophora. Overall, we were able to relate the mineral (iron, calcium) content with the mechanical parameters (hardness and Young's modulus) and the breaking force and stress in every tooth type. This led to a better understanding of the relationship between structure, material, and function in radular teeth. Further, we aimed at determining the role of calcium for the mechanical behaviour of the teeth: we decalcified radulae by ethylene diamine tetra acetic acid and performed afterwards elemental analyses, breaking stress experiments, and nanoindentation. Among other things, we detected that wet and decalcified radular teeth could resist highest forces, since teeth have a higher range of bending motion leading to a higher capability of teeth to gain mechanical support from the adjacent tooth row. This indicates, that the tooth material is the result of a compromise between failure reduction and the ability to transfer forces onto the ingesta.
We present novel data on the elemental composition, mechanical properties, and the mechanical behaviour of chiton teeth, which allows conclusions about tooth function. We could also relate the parameters mentioned, which contributes to our understanding on the origins of mechanical property gradients and the processes reducing structural failure in radular teeth. Additionally, we add more evidence, that the elemental composition of radular is probably species-specific and could be used as taxonomic character.
齿舌是一种嵌入齿的几丁质膜,是软体动物的一个重要自近裔性状。在过去几十年里,对某些分类群(多板纲和笠贝亚纲)中的一种齿型(主要侧齿)的机械性能、化学和结构组成以及这些参数之间的关系进行了深入研究。由于主要侧齿可能是研究得最透彻的生物材料之一,令人惊讶的是,关于石鳖齿舌上其他齿型的元素和机械性能的数据却很缺乏。
我们提供了多板纲灰石鳖(Lepidochitona cinerea,林奈,1767年)[石鳖科:薄石鳖科]所有齿的元素分布和机械性能(硬度和弹性,即杨氏模量)的数据。通过能量色散X射线光谱研究了各齿型中元素的个体发育,并通过纳米压痕法测定了机械性能的个体发育。此外,我们对干燥和湿润条件下的齿进行了断裂应力实验,突出了含水量对齿舌机械行为的高度影响。由此我们能够确定齿所能承受的力和应力,而此前多板纲的代表物种中尚未对此进行过研究。总体而言,我们能够将矿物(铁、钙)含量与各齿型的机械参数(硬度和杨氏模量)以及断裂力和应力联系起来。这有助于更好地理解齿舌齿的结构、材料和功能之间的关系。此外,我们旨在确定钙对齿机械行为的作用:我们用乙二胺四乙酸对齿舌进行脱钙处理,然后进行元素分析、断裂应力实验和纳米压痕。除其他发现外,我们检测到湿润和脱钙的齿舌齿能承受最高的力,因为齿具有更大的弯曲运动范围,从而使齿从相邻齿排获得机械支撑的能力更强。这表明,齿材料是减少失效和将力传递到食物上的能力之间折衷的结果。
我们提供了关于石鳖齿的元素组成、机械性能和机械行为的新数据,这些数据有助于推断齿的功能。我们还能够关联上述参数,这有助于我们理解机械性能梯度的起源以及减少齿舌齿结构失效的过程。此外,我们补充了更多证据,表明齿舌的元素组成可能具有物种特异性,可作为分类特征。
