Organ Systems of a Cambrian Euarthropod Larva

Overview

Journal Nature

Specialty Science

Date 2024 Jul 31

PMID 39085610

Authors

Martin R Smith

Emma J Long

Alavya Dhungana

Katherine J Dobson

Jie Yang

Xiguang Zhang

Affiliations

Soon will be listed here.

Abstract

The Cambrian radiation of euarthropods can be attributed to an adaptable body plan. Sophisticated brains and specialized feeding appendages, which are elaborations of serially repeated organ systems and jointed appendages, underpin the dominance of Euarthropoda in a broad suite of ecological settings. The origin of the euarthropod body plan from a grade of vermiform taxa with hydrostatic lobopodous appendages ('lobopodian worms') is founded on data from Burgess Shale-type fossils. However, the compaction associated with such preservation obscures internal anatomy. Phosphatized microfossils provide a complementary three-dimensional perspective on early crown group euarthropods, but few lobopodians. Here we describe the internal and external anatomy of a three-dimensionally preserved euarthropod larva with lobopods, midgut glands and a sophisticated head. The architecture of the nervous system informs the early configuration of the euarthropod brain and its associated appendages and sensory organs, clarifying homologies across Panarthropoda. The deep evolutionary position of Youti yuanshi gen. et sp. nov. informs the sequence of character acquisition during arthropod evolution, demonstrating a deep origin of sophisticated haemolymph circulatory systems, and illuminating the internal anatomical changes that propelled the rise and diversification of this enduringly successful group.

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