Putative hydroid symbionts recorded by bioclaustrations in fossil molluscan shells: a revision and reinterpretation of the cecidogenus Rodocanalis

IF 2.3 2区地球科学 Q1 PALEONTOLOGY

Papers in Palaeontology Pub Date : 2023-03-01 DOI:10.1002/spp2.1484

M. Wisshak, S. Schneider, R. Mikuláš, S. Richiano, F. Ramil, Mark A. Wilson

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引用次数: 1

Abstract

The fossil record yields a peculiar phenomenon in different kinds of molluscan shells: bioclaustrations formed around (epi)symbionts during growth of the hosts' shell margin. Four morphologies, two of them formerly considered bioerosion traces, are here united in the parataxonomy of bioclaustration structures under the revised cecidogenus Rodocanalis. These are: (1) simple linear grooves (Rodocanalis linearis csp. nov.) formed below the periostracum in Pleistocene to Recent endobenthic bivalves; (2) series of distally ramifying grooves (Rodocanalis runicus) in Silurian orthoconic nautiloids; (3) irregular networks of grooves (Rodocanalis reticulatus) in Jurassic to Cretaceous bivalves and gastropods; and (4) regular reticulate networks (Rodocanalis geometricus csp. nov.) in Jurassic to Cretaceous gastropods. The linear grooves might be associated with commensal worms, while multiple lines of reasoning point towards hydrozoan symbionts in the case of the branched and anastomosing grooves. After the hydrozoan larva settles and the first polyp becomes fixed on the calcareous ostracum at the shell margin, the process of bioclaustration commences when the periostracum surrounds the base of the polyp, which moves towards the external shell surface, while the hydrorhizae develop in the only possible direction: towards the shell growth margin. This enables new polyps to originate at the shell edge by budding, while the bioclaustration of the stolonial hydrorhizae advances. We consider the nature of this symbiotic relationship as mutualism, with the hydrozoan symbiont taking advantage of the host's feeding current or food debris, and the molluscan host profiting from the defensive capability of the hydrozoan's cnidocysts.

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软体动物化石壳中生物关闭所记录的假定的水螅共生体:对香蚊属的修正和重新解释

化石记录在不同种类的软体动物壳中发现了一种奇特的现象:在寄主壳缘生长过程中，共生体周围形成了生物聚束。四种形态，其中两种以前被认为是生物侵蚀的痕迹，在这里统一在修订的塞蚊属Rodocanalis下的生物闭锁结构的准分类学中。这些是:(1)简单线性凹槽(Rodocanalis linearis csp)。11)形成于更新世至近代底栖双壳类动物的膜下;(2)志留纪正圆锥鹦鹉螺的远端分枝凹槽系列(Rodocanalis runicus);(3)侏罗纪至白垩纪双壳类和腹足类动物的不规则凹槽网(Rodocanalis reticulatus);(4)规则网状网络(Rodocanalis geometricus)。11月)侏罗纪到白垩纪腹足类。线性沟槽可能与共生蠕虫有关，而分支和吻合沟槽的多条推理指向水生动物共生体。当水螅虫幼虫定居下来，第一个水螅固定在壳缘的钙质介形层上后，当水螅体的膜膜围绕着基部时，水螅体就开始了生物闭锁过程，水螅体向外壳表面移动，而水螅体则向唯一可能的方向发育:向壳缘生长。这使得新的水螅通过出芽在壳边缘产生，而匍匐茎的水根的生物闭合也在推进。我们认为这种共生关系的本质是互惠共生，水生动物共生体利用宿主的进食电流或食物残渣，而软体动物宿主则从水生动物的刺胞囊的防御能力中获利。

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来源期刊

Papers in Palaeontology PALEONTOLOGY-

CiteScore

4.50

自引率

4.30%

发文量

期刊介绍： Papers in Palaeontology is the successor to Special Papers in Palaeontology and a journal of the Palaeontological Association (www.palass.org). The journal is devoted to the publication of papers that document the diversity of past life and its distribution in time and space. Papers in Palaeontology is devoted to the publication of papers that document the diversity of past life and its distribution in time and space. As a sister publication to Palaeontology its focus is on descriptive research, including the descriptions of new taxa, systematic revisions of higher taxa, detailed biostratigraphical and biogeographical documentation, and descriptions of floras and faunas from specific localities or regions. Most contributions are expected to be less than 30 pp long but longer contributions will be considered if the material merits it, including single topic parts. The journal publishes a wide variety of papers on palaeontological topics covering: palaeozoology, palaeobotany, systematic studies, palaeoecology, micropalaeontology, palaeobiogeography, functional morphology, stratigraphy, taxonomy, taphonomy, palaeoenvironmental reconstruction, palaeoclimate analysis, biomineralization studies.