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果蝇古演化发育生物学:波罗的海和比特费尔德琥珀中双翅目毛蚊亚目的未成熟阶段

Fly palaeo-evo-devo: immature stages of bibionomorphan dipterans in Baltic and Bitterfeld amber.

作者信息

Baranov Viktor A, Schädel Mario, Haug Joachim T

机构信息

Biology II, Ludwig-Maximilians-Universität München, Planegg, Bayern, Germany.

Geobio-Center, Ludwig-Maximilians-Universität München, München, Bayern, Germany.

出版信息

PeerJ. 2019 Oct 10;7:e7843. doi: 10.7717/peerj.7843. eCollection 2019.

DOI:10.7717/peerj.7843
PMID:31616596
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6790230/
Abstract

Larvae of flies and gnats (Diptera) form a crucial component of many terrestrial and freshwater ecosystems in the extant biosphere. Larvae of Diptera play a central role in water purification, matter and energy transfer in riparian ecosystems in rivers, carbon cycling in lakes and forests as well as being major decomposers of dead organic matter. Despite all these important roles, dipteran larvae are most often ignored in palaeoecological studies, due to the difficulty of the taxonomic identification of fossil larvae, but also due to the perceived importance of adult dipterans in palaeoentomological and taxonomic studies. Despite that, much information on palaeoecosystems can be gained from studying fossil dipteran larvae, in particular for well preserved specimens from fossil resins (ambers and copals). Since ambers are selectively preserving fauna of trunks and leaf litter, it allows us to learn a lot about xylophages and saprophages of amber forests, such as Eocene Baltic amber forest. Here we present immature stages (larvae and pupae) of the dipteran ingroup Bibionomorpha, from Baltic and Bitterfeld amber forests. We have recorded at least four different larval morphotypes, one with four distinct instars, and at least three pupal morphotypes. One larva is recognised as a new species and can be interpreted either as a representative of a highly derived ingroup of Bibionidae or as a sister species to Bibionidae. Also represented by single larval specimens are the groups (Pachyneuridae) and (Anisopodidae). The majority of the recorded specimens are representatives of the group (Anisopodidae). Due to the abundance of immature stages of , we have been able to reconstruct the number of larval stages (4) and relative growth rate of these fossil dipterans. We discuss implications of these finds.

摘要

苍蝇和蚋(双翅目)的幼虫是现存生物圈中许多陆地和淡水生态系统的重要组成部分。双翅目幼虫在水净化、河流沿岸生态系统中的物质和能量转移、湖泊和森林中的碳循环以及作为死有机物质的主要分解者方面发挥着核心作用。尽管有这些重要作用,但在古生态学研究中,双翅目幼虫最常被忽视,这不仅是因为化石幼虫的分类鉴定困难,还因为成虫双翅目在古昆虫学和分类学研究中被认为具有重要性。尽管如此,通过研究化石双翅目幼虫,尤其是来自化石树脂(琥珀和柯巴脂)中保存完好的标本,可以获得许多关于古生态系统的信息。由于琥珀有选择地保存树干和落叶层的动物群,这使我们能够了解很多关于琥珀森林中的蛀木虫和腐食性昆虫的信息,比如始新世波罗的海琥珀森林。在这里,我们展示了来自波罗的海和比特费尔德琥珀森林的双翅目内类群毛蚊亚目的未成熟阶段(幼虫和蛹)。我们记录了至少四种不同的幼虫形态类型,一种有四个不同的龄期,以及至少三种蛹的形态类型。一种幼虫被认定为一个新物种,可以被解释为毛蚊科一个高度特化内类群的代表,或者是毛蚊科的一个姐妹物种。(粗脉毛蚊科)和(长足蚋科)也由单个幼虫标本代表。记录的标本大多数是(长足蚋科)的代表。由于(长足蚋科)未成熟阶段数量众多,我们得以重建这些化石双翅目昆虫的幼虫龄期数量(4个)和相对生长速率。我们讨论了这些发现的意义。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9a1c/6790230/b729014c6f7e/peerj-07-7843-g019.jpg
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