Biomaterial evolution parallels behavioral innovation in the origin of orb-like spider webs

Todd A. Blackledge; Matjaž Kuntner; Mohammad Marhabaie; Thomas C. Leeper; Ingi Agnarsson

doi:10.1038/srep00833

Biomaterial evolution parallels behavioral innovation in the origin of orb-like spider webs

Todd A. Blackledge, Matjaž Kuntner, Mohammad Marhabaie, Thomas C. Leeper, Ingi Agnarsson

Faculty of Life and Environmental Sciences

University of Iceland

Research output: Contribution to journal › Article › peer-review

Abstract

Correlated evolution of traits can act synergistically to facilitate organism function. But, what happens when constraints exist on the evolvability of some traits, but not others? The orb web was a key innovation in the origin of >12,000 species of spiders. Orb evolution hinged upon the origin of novel spinning behaviors and innovations in silk material properties. In particular, a new major ampullate spidroin protein (MaSp2) increased silk extensibility and toughness, playing a critical role in how orb webs stop flying insects. Here, we show convergence between pseudo-orb-weaving Fecenia and true orb spiders. As in the origin of true orbs, Fecenia dragline silk improved significantly compared to relatives. But, Fecenia silk lacks the high compliance and extensibility found in true orb spiders, likely due in part to the absence of MaSp2. Our results suggest how constraints limit convergent evolution and provide insight into the evolution of nature's toughest fibers.

Original language	English
Article number	833
Journal	Scientific Reports
Volume	2
DOIs	https://doi.org/10.1038/srep00833
Publication status	Published - 2012

Bibliographical note

Funding Information: We thank S. Zschokke, M. Herberstein, and an anonymous reviewer for insightful comments on earlier drafts of the manuscript. D. Piorkowski provided assistance with the collection and mechanical testing of silk. S. Bilinovich provided support for the HPLC. M. Gregoricˇ and D. Li helped with field collection and/or DNA sequencing. S. Richards and the Conservation International RAP program sponsored and organized fieldwork in Papua. Work was supported by NSF grants no. IOS-0745379 and DEB-1050187–1050253 and by the Slovenian Research Agency grant no. J1 – 2063. Sequences were deposited in GenBank with accession numbers (KC011009-11021).

Access to Document

10.1038/srep00833

Cite this

@article{5a93a7dd38e144dc9510a88274a54d16,

title = "Biomaterial evolution parallels behavioral innovation in the origin of orb-like spider webs",

abstract = "Correlated evolution of traits can act synergistically to facilitate organism function. But, what happens when constraints exist on the evolvability of some traits, but not others? The orb web was a key innovation in the origin of >12,000 species of spiders. Orb evolution hinged upon the origin of novel spinning behaviors and innovations in silk material properties. In particular, a new major ampullate spidroin protein (MaSp2) increased silk extensibility and toughness, playing a critical role in how orb webs stop flying insects. Here, we show convergence between pseudo-orb-weaving Fecenia and true orb spiders. As in the origin of true orbs, Fecenia dragline silk improved significantly compared to relatives. But, Fecenia silk lacks the high compliance and extensibility found in true orb spiders, likely due in part to the absence of MaSp2. Our results suggest how constraints limit convergent evolution and provide insight into the evolution of nature's toughest fibers.",

author = "Blackledge, \{Todd A.\} and Matja{\v z} Kuntner and Mohammad Marhabaie and Leeper, \{Thomas C.\} and Ingi Agnarsson",

note = "Funding Information: We thank S. Zschokke, M. Herberstein, and an anonymous reviewer for insightful comments on earlier drafts of the manuscript. D. Piorkowski provided assistance with the collection and mechanical testing of silk. S. Bilinovich provided support for the HPLC. M. Gregoricˇ and D. Li helped with field collection and/or DNA sequencing. S. Richards and the Conservation International RAP program sponsored and organized fieldwork in Papua. Work was supported by NSF grants no. IOS-0745379 and DEB-1050187–1050253 and by the Slovenian Research Agency grant no. J1 – 2063. Sequences were deposited in GenBank with accession numbers (KC011009-11021).",

year = "2012",

doi = "10.1038/srep00833",

language = "English",

volume = "2",

journal = "Scientific Reports",

issn = "2045-2322",

publisher = "Nature Research",

}

TY - JOUR

T1 - Biomaterial evolution parallels behavioral innovation in the origin of orb-like spider webs

AU - Blackledge, Todd A.

AU - Kuntner, Matjaž

AU - Marhabaie, Mohammad

AU - Leeper, Thomas C.

AU - Agnarsson, Ingi

N1 - Funding Information: We thank S. Zschokke, M. Herberstein, and an anonymous reviewer for insightful comments on earlier drafts of the manuscript. D. Piorkowski provided assistance with the collection and mechanical testing of silk. S. Bilinovich provided support for the HPLC. M. Gregoricˇ and D. Li helped with field collection and/or DNA sequencing. S. Richards and the Conservation International RAP program sponsored and organized fieldwork in Papua. Work was supported by NSF grants no. IOS-0745379 and DEB-1050187–1050253 and by the Slovenian Research Agency grant no. J1 – 2063. Sequences were deposited in GenBank with accession numbers (KC011009-11021).

PY - 2012

Y1 - 2012

N2 - Correlated evolution of traits can act synergistically to facilitate organism function. But, what happens when constraints exist on the evolvability of some traits, but not others? The orb web was a key innovation in the origin of >12,000 species of spiders. Orb evolution hinged upon the origin of novel spinning behaviors and innovations in silk material properties. In particular, a new major ampullate spidroin protein (MaSp2) increased silk extensibility and toughness, playing a critical role in how orb webs stop flying insects. Here, we show convergence between pseudo-orb-weaving Fecenia and true orb spiders. As in the origin of true orbs, Fecenia dragline silk improved significantly compared to relatives. But, Fecenia silk lacks the high compliance and extensibility found in true orb spiders, likely due in part to the absence of MaSp2. Our results suggest how constraints limit convergent evolution and provide insight into the evolution of nature's toughest fibers.

AB - Correlated evolution of traits can act synergistically to facilitate organism function. But, what happens when constraints exist on the evolvability of some traits, but not others? The orb web was a key innovation in the origin of >12,000 species of spiders. Orb evolution hinged upon the origin of novel spinning behaviors and innovations in silk material properties. In particular, a new major ampullate spidroin protein (MaSp2) increased silk extensibility and toughness, playing a critical role in how orb webs stop flying insects. Here, we show convergence between pseudo-orb-weaving Fecenia and true orb spiders. As in the origin of true orbs, Fecenia dragline silk improved significantly compared to relatives. But, Fecenia silk lacks the high compliance and extensibility found in true orb spiders, likely due in part to the absence of MaSp2. Our results suggest how constraints limit convergent evolution and provide insight into the evolution of nature's toughest fibers.

UR - https://www.scopus.com/pages/publications/84869161175

U2 - 10.1038/srep00833

DO - 10.1038/srep00833

M3 - Article

C2 - 23150784

SN - 2045-2322

VL - 2

JO - Scientific Reports

JF - Scientific Reports

M1 - 833

ER -

Biomaterial evolution parallels behavioral innovation in the origin of orb-like spider webs

Abstract

Bibliographical note

Access to Document

Fingerprint

Cite this