Chia Chia Tan scite author profile

Background: Sortase A (SrtA) is a transpeptidase capable of catalyzing the formation of amide bonds. Results: SrtA was used to backbone-cyclize disulfide-rich peptides, including kalata B1, ␣-conotoxin Vc1.1, and SFTI-1. Conclusion: SrtA-mediated cyclization is applicable to small disulfide-rich peptides. Significance: SrtA-mediated cyclization is an alternative to native chemical ligation for the cyclization of small peptides of therapeutic interest.

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Structure of α-conotoxin BuIA: influences of disulfide connectivity on structural dynamics

Jin

Brandstaetter

Nevin

et al. 2007

BMC Struct Biol

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Backgroundα-Conotoxins have exciting therapeutic potential based on their high selectivity and affinity for nicotinic acetylcholine receptors. The spacing between the cysteine residues in α-conotoxins is variable, leading to the classification of sub-families. BuIA is the only α-conotoxin containing a 4/4 cysteine spacing and thus it is of significant interest to examine the structure of this conotoxin.ResultsIn the current study we show the native globular disulfide connectivity of BuIA displays multiple conformations in solution whereas the non-native ribbon isomer has a single well-defined conformation. Despite having multiple conformations in solution the globular form of BuIA displays activity at the nicotinic acetylcholine receptor, contrasting with the lack of activity of the structurally well-defined ribbon isomer.ConclusionThese findings are opposite to the general trends observed for α-conotoxins where the native isomers have well-defined structures and the ribbon isomers are generally disordered. This study thus highlights the influence of the disulfide connectivity of BuIA on the dynamics of the three-dimensional structure.

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Structural and Functional Analysis of Human Liver‐Expressed Antimicrobial Peptide 2

et al. 2010

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Human liver-expressed antimicrobial peptide 2 (LEAP-2) is a cationic antimicrobial peptide (CAMP) believed to have a protective role against bacterial infection. Little is known about the structure-activity relationships of LEAP-2 or its mechanism of action. In this study we describe the structure of LEAP-2, analyze its interaction with model membranes, and relate them to the antimicrobial activity of the peptide. The structure of LEAP-2, determined by NMR spectroscopy, reveals a compact central core with disorder at the N and C termini. The core comprises a β-hairpin and a 3(10)- helix that are braced by disulfide bonds between Cys17-28 and Cys23-33 and further stabilized by a network of hydrogen bonds. Membrane-affinity studies show that LEAP-2 membrane binding is governed by electrostatic attractions, which are sensitive to ionic strength. Truncation studies show that the C-terminal region of LEAP-2 is irrelevant for membrane binding, whereas the N-terminal (hydrophobic domain) and core regions (cationic domain) are essential. Bacterial-growth-inhibition assays reveal that the antimicrobial activity of LEAP-2 correlates with membrane affinity. Interestingly, the native and reduced forms of LEAP-2 have similar membrane affinity and antimicrobial activities; this suggests that disulfide bonds are not essential for the bactericidal activity. This study reveals that LEAP-2 has a novel fold for a CAMP and suggests that although LEAP-2 exhibits antimicrobial activity under low-salt conditions, there is likely to be another physiological role for the peptide.

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Understanding the Structure/Activity Relationships of the Iron Regulatory Peptide Hepcidin

Clark¹,

Tan²,

Preza³

et al. 2011

Chemistry & Biology

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Summary The peptide hormone hepcidin is a key homeostatic regulator of iron metabolism and involved in pathological regulation of iron in response to infection, inflammation, hypoxia and anaemia. It acts by binding to the iron exporter ferroportin, causing it to be internalised and degraded; however, little is known about the structure/activity relationships of the interaction of hepcidin with ferroportin. Here we show that there are key residues within the N-terminal region of hepcidin that influence its interaction with ferroportin, and we explore the structure/function relationships at these positions. We found that the interaction is primarily hydrophobic with critical stereochemical requirements at positions 4 and 6. In addition, a series of hepcidin mutants in which disulfide bonds had been replaced with diselenide bonds showed no change in biological activity compared to native hepcidin. The results provide mechanistic insight into the interaction between hepcidin and ferroportin and identify important constraints for the development of hepcidin congeners for the treatment of hereditary iron overload.

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Chia Chia Tan

Semienzymatic Cyclization of Disulfide-rich Peptides Using Sortase A

Structure of α-conotoxin BuIA: influences of disulfide connectivity on structural dynamics

Structural and Functional Analysis of Human Liver‐Expressed Antimicrobial Peptide 2

Understanding the Structure/Activity Relationships of the Iron Regulatory Peptide Hepcidin

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