Evolutionary Adaptations to Cysteine-rich Peptide Folding

Helena Safavi-Hemami; Mads Møller Foged; Lars Ellgaard

doi:10.1039/9781788013253

Evolutionary Adaptations to Cysteine-rich Peptide Folding

Helena Safavi-Hemami, Mads Møller Foged, Lars Ellgaard

Abstract

Cysteine-rich peptides are highly abundant in nature, and provide a fascinating insight into protein folding, structure, chemical modification and function. The largest number and diversity of cysteine-rich peptides are produced by organisms at the interface between predator and prey, and host and pathogen (or symbiont). The small peptides produced by these organisms are characterized by hypervariable sequences interspersed with conserved cysteines involved in disulfide bond formation, and include some of the fastest evolving genes in nature. The diversity of structural scaffolds found for cysteine-rich peptides suggests that specialized adaptations have evolved to ensure their efficient folding and secretion in their producer organisms. This chapter uses conopeptides, neurotoxic peptides found in the venoms of predatory marine cone snails, as model systems to discuss some of these adaptations discovered in organisms that provide a rich source of cysteine-rich peptides with diverse structural scaffolds.

Original language	English
Title of host publication	Oxidative Folding of Proteins : Basic Principles, Cellular Regulation and Engineering
Editors	Matthias J. Feige
Number of pages	30
Publisher	Royal Society of Chemistry
Publication date	2018
Pages	99-128
Chapter	2.1
ISBN (Print)	978-1-78262-990-0
ISBN (Electronic)	978-1-78801-485-4
DOIs	https://doi.org/10.1039/9781788013253
Publication status	Published - 2018

Series	Chemical Biology
Volume	9
ISSN	2055-1975

Access to Document

10.1039/9781788013253

Cite this

Evolutionary Adaptations to Cysteine-rich Peptide Folding. / Safavi-Hemami, Helena; Foged, Mads Møller; Ellgaard, Lars.

Oxidative Folding of Proteins: Basic Principles, Cellular Regulation and Engineering . ed. / Matthias J. Feige. Royal Society of Chemistry, 2018. p. 99-128 (Chemical Biology, Vol. 9).

Research output: Chapter in Book/Report/Conference proceeding › Book chapter › Research › peer-review

@inbook{d40a9a0d82b44ab0ac5816534af92e75,

title = "Evolutionary Adaptations to Cysteine-rich Peptide Folding",

abstract = "Cysteine-rich peptides are highly abundant in nature, and provide a fascinating insight into protein folding, structure, chemical modification and function. The largest number and diversity of cysteine-rich peptides are produced by organisms at the interface between predator and prey, and host and pathogen (or symbiont). The small peptides produced by these organisms are characterized by hypervariable sequences interspersed with conserved cysteines involved in disulfide bond formation, and include some of the fastest evolving genes in nature. The diversity of structural scaffolds found for cysteine-rich peptides suggests that specialized adaptations have evolved to ensure their efficient folding and secretion in their producer organisms. This chapter uses conopeptides, neurotoxic peptides found in the venoms of predatory marine cone snails, as model systems to discuss some of these adaptations discovered in organisms that provide a rich source of cysteine-rich peptides with diverse structural scaffolds.",

author = "Helena Safavi-Hemami and Foged, {Mads M{\o}ller} and Lars Ellgaard",

year = "2018",

doi = "10.1039/9781788013253",

language = "English",

isbn = "978-1-78262-990-0",

series = "Chemical Biology",

publisher = "Royal Society of Chemistry",

pages = "99--128",

editor = "Feige, {Matthias J.}",

booktitle = "Oxidative Folding of Proteins",

address = "United Kingdom",

}

TY - CHAP

T1 - Evolutionary Adaptations to Cysteine-rich Peptide Folding

AU - Safavi-Hemami, Helena

AU - Foged, Mads Møller

AU - Ellgaard, Lars

PY - 2018

Y1 - 2018

N2 - Cysteine-rich peptides are highly abundant in nature, and provide a fascinating insight into protein folding, structure, chemical modification and function. The largest number and diversity of cysteine-rich peptides are produced by organisms at the interface between predator and prey, and host and pathogen (or symbiont). The small peptides produced by these organisms are characterized by hypervariable sequences interspersed with conserved cysteines involved in disulfide bond formation, and include some of the fastest evolving genes in nature. The diversity of structural scaffolds found for cysteine-rich peptides suggests that specialized adaptations have evolved to ensure their efficient folding and secretion in their producer organisms. This chapter uses conopeptides, neurotoxic peptides found in the venoms of predatory marine cone snails, as model systems to discuss some of these adaptations discovered in organisms that provide a rich source of cysteine-rich peptides with diverse structural scaffolds.

AB - Cysteine-rich peptides are highly abundant in nature, and provide a fascinating insight into protein folding, structure, chemical modification and function. The largest number and diversity of cysteine-rich peptides are produced by organisms at the interface between predator and prey, and host and pathogen (or symbiont). The small peptides produced by these organisms are characterized by hypervariable sequences interspersed with conserved cysteines involved in disulfide bond formation, and include some of the fastest evolving genes in nature. The diversity of structural scaffolds found for cysteine-rich peptides suggests that specialized adaptations have evolved to ensure their efficient folding and secretion in their producer organisms. This chapter uses conopeptides, neurotoxic peptides found in the venoms of predatory marine cone snails, as model systems to discuss some of these adaptations discovered in organisms that provide a rich source of cysteine-rich peptides with diverse structural scaffolds.

U2 - 10.1039/9781788013253

DO - 10.1039/9781788013253

M3 - Book chapter

SN - 978-1-78262-990-0

T3 - Chemical Biology

SP - 99

EP - 128

BT - Oxidative Folding of Proteins

A2 - Feige, Matthias J.

PB - Royal Society of Chemistry

ER -