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Main Authors: Papadopoulos, Nikolaos, Kulkarni, Siddharth S, Baranyi, Christian, Fromm, Bastian, Setton, Emily V W, Sharma, Prashant P, Wanninger, Andreas, Brenneis, Georg
Format: Artículo científico
Language:en
Published: BMC biology 2025
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Online Access:https://pubmed.ncbi.nlm.nih.gov/40598291/
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author Papadopoulos, Nikolaos
Kulkarni, Siddharth S
Baranyi, Christian
Fromm, Bastian
Setton, Emily V W
Sharma, Prashant P
Wanninger, Andreas
Brenneis, Georg
author_facet Papadopoulos, Nikolaos
Kulkarni, Siddharth S
Baranyi, Christian
Fromm, Bastian
Setton, Emily V W
Sharma, Prashant P
Wanninger, Andreas
Brenneis, Georg
Papadopoulos, Nikolaos
Kulkarni, Siddharth S
Baranyi, Christian
Fromm, Bastian
Setton, Emily V W
Sharma, Prashant P
Wanninger, Andreas
Brenneis, Georg
collection PubMed - marine biology
contents The genome of a sea spider corroborates a shared Hox cluster motif in arthropods with a reduced posterior tagma. Papadopoulos, Nikolaos Kulkarni, Siddharth S Baranyi, Christian Fromm, Bastian Setton, Emily V W Sharma, Prashant P Wanninger, Andreas Brenneis, Georg Animals Genome Genes, Homeobox Phylogeny Arthropods Multigene Family Evolution, Molecular Chelicerate evolution is contentiously debated, with recent studies challenging traditional phylogenetic hypotheses and scenarios of major evolutionary events, like terrestrialization. Sea spiders (Pycnogonida) represent the uncontested marine sister group of all other chelicerates, featuring a-likely plesiomorphic-indirect development. Accordingly, pycnogonids hold the potential to provide crucial insight into the evolution of chelicerate genomes and body patterning. Due to the lack of high-quality genomic and transcriptomic resources, however, this potential remains largely unexplored. We employ long-read sequencing and proximity ligation data to assemble the first near chromosome-level sea spider genome for Pycnogonum litorale, complemented by comprehensive transcriptomic resources. The assembly has a size of 471 Mb in 57 pseudochromosomes, a repeat content of 61.05%, 15,372 predicted protein-coding genes, and robust completeness scores (95.8% BUSCO Arthropoda score, 95.7% of conserved microRNA families). Genome-scale self-synteny and homeobox gene cluster analysis show no evidence of a whole-genome duplication (WGD). We identify a single, intact Hox cluster lacking Abdominal-A (abdA/Hox9), corroborated by the absence of an abdA ortholog in the novel transcriptomic resources. Our high-quality genomic and transcriptomic resources establish P. litorale as a key research organism for modern studies on chelicerate genome evolution, development, and phylogeny. The lack of WGD signature in P. litorale further strengthens the inference that WGDs are derived traits in the chelicerate tree. The combination of abdA loss with the reduction of the posterior tagma emerges as a common theme in arthropod evolution, as it is shared with other, distantly related arthropod taxa with a vestigial opisthosoma/abdomen.
format Artículo científico
id pubmed_40598291
institution PubMed
language en
publishDate 2025
publisher BMC biology
record_format pubmed
spellingShingle The genome of a sea spider corroborates a shared Hox cluster motif in arthropods with a reduced posterior tagma.
Papadopoulos, Nikolaos
Kulkarni, Siddharth S
Baranyi, Christian
Fromm, Bastian
Setton, Emily V W
Sharma, Prashant P
Wanninger, Andreas
Brenneis, Georg
Animals
Genome
Genes, Homeobox
Phylogeny
Arthropods
Multigene Family
Evolution, Molecular
The genome of a sea spider corroborates a shared Hox cluster motif in arthropods with a reduced posterior tagma. Papadopoulos, Nikolaos Kulkarni, Siddharth S Baranyi, Christian Fromm, Bastian Setton, Emily V W Sharma, Prashant P Wanninger, Andreas Brenneis, Georg Animals Genome Genes, Homeobox Phylogeny Arthropods Multigene Family Evolution, Molecular Chelicerate evolution is contentiously debated, with recent studies challenging traditional phylogenetic hypotheses and scenarios of major evolutionary events, like terrestrialization. Sea spiders (Pycnogonida) represent the uncontested marine sister group of all other chelicerates, featuring a-likely plesiomorphic-indirect development. Accordingly, pycnogonids hold the potential to provide crucial insight into the evolution of chelicerate genomes and body patterning. Due to the lack of high-quality genomic and transcriptomic resources, however, this potential remains largely unexplored. We employ long-read sequencing and proximity ligation data to assemble the first near chromosome-level sea spider genome for Pycnogonum litorale, complemented by comprehensive transcriptomic resources. The assembly has a size of 471 Mb in 57 pseudochromosomes, a repeat content of 61.05%, 15,372 predicted protein-coding genes, and robust completeness scores (95.8% BUSCO Arthropoda score, 95.7% of conserved microRNA families). Genome-scale self-synteny and homeobox gene cluster analysis show no evidence of a whole-genome duplication (WGD). We identify a single, intact Hox cluster lacking Abdominal-A (abdA/Hox9), corroborated by the absence of an abdA ortholog in the novel transcriptomic resources. Our high-quality genomic and transcriptomic resources establish P. litorale as a key research organism for modern studies on chelicerate genome evolution, development, and phylogeny. The lack of WGD signature in P. litorale further strengthens the inference that WGDs are derived traits in the chelicerate tree. The combination of abdA loss with the reduction of the posterior tagma emerges as a common theme in arthropod evolution, as it is shared with other, distantly related arthropod taxa with a vestigial opisthosoma/abdomen.
title The genome of a sea spider corroborates a shared Hox cluster motif in arthropods with a reduced posterior tagma.
topic Animals
Genome
Genes, Homeobox
Phylogeny
Arthropods
Multigene Family
Evolution, Molecular
url https://pubmed.ncbi.nlm.nih.gov/40598291/