Your search keyword '"Rosengren, K. Johan"' showing total 11 results

1. Three-Dimensional Structure Determination of Peptides Using Solution Nuclear Magnetic Resonance Spectroscopy.

Author

Schroeder CI and Rosengren KJ

Subjects

Protein Conformation, Magnetic Resonance Spectroscopy methods, Peptides chemistry, Proteins chemistry

Abstract

Nuclear magnetic resonance (NMR) spectroscopy has over the last few decades proven to be an extremely useful technique for, and indeed an integral part of, investigating the structural features of peptides and small proteins directly in solution, without the need for crystallization. This advantage over X-ray methods is important when dealing with peptides and small proteins that do not readily form crystals. In this chapter we outline what specific NMR experiments are useful, considerations about how to acquire and interpret these experiments, and how information derived from the NMR data can be used to determine solution structures of small peptides.

Published

2020

2. Relaxin family peptides: structure-activity relationship studies.

Author

Patil NA, Rosengren KJ, Separovic F, Wade JD, Bathgate RAD, and Hossain MA

Subjects

Humans, Models, Molecular, Relaxin chemistry, Structure-Activity Relationship, Insulin chemistry, Proteins chemistry, Relaxin analogs & derivatives

Abstract

The human relaxin peptide family consists of seven cystine-rich peptides, four of which are known to signal through relaxin family peptide receptors, RXFP1-4. As these peptides play a vital role physiologically and in various diseases, they are of considerable importance for drug discovery and development. Detailed structure-activity relationship (SAR) studies towards understanding the role of important residues in each of these peptides have been reported over the years and utilized for the design of antagonists and minimized agonist variants. This review summarizes the current knowledge of the SAR of human relaxin 2 (H2 relaxin), human relaxin 3 (H3 relaxin), human insulin-like peptide 3 (INSL3) and human insulin-like peptide 5 (INSL5)., Linked Articles: This article is part of a themed section on Recent Progress in the Understanding of Relaxin Family Peptides and their Receptors. To view the other articles in this section visit http://onlinelibrary.wiley.com/doi/10.1111/bph.v174.10/issuetoc., (© 2016 The British Pharmacological Society.)

Published

2017

3. Engineering of a Novel Simplified Human Insulin-Like Peptide 5 Agonist.

Author

Patil NA, Hughes RA, Rosengren KJ, Kocan M, Ang SY, Tailhades J, Separovic F, Summers RJ, Grosse J, Wade JD, Bathgate RA, and Hossain MA

Subjects

Animals, CHO Cells, Cricetulus, Dose-Response Relationship, Drug, Humans, Mice, Models, Molecular, Molecular Structure, Peptides chemical synthesis, Peptides chemistry, Structure-Activity Relationship, Insulin agonists, Peptides pharmacology, Protein Engineering, Proteins agonists

Abstract

Insulin-like peptide 5 (INSL5) has recently been discovered as only the second orexigenic gut hormone after ghrelin. As we have previously reported, INSL5 is extremely difficult to assemble and oxidize into its two-chain three-disulfide structure. The focus of this study was to generate structure-activity relationships (SARs) of INSL5 and use it to develop a potent and simpler INSL5 mimetic with RXFP4 agonist activity. A series of human and mouse INSL5 (hINSL5/mINSL5) analogues were designed and chemically synthesized, resulting in a chimeric INSL5 analogue exhibiting more than 10-fold higher potency (0.35 nM) at human RXFP4 compared with native hINSL5 (4.57 nM). The SAR study also identified a key residue (K(A15)) in the A-chain of mINSL5 that contributes to improved RXFP4 affinity and potency of mINSL5 compared with hINSL5. This knowledge ultimately led us to engineer a minimized hINSL5 mimetic agonist that retains native hINSL5-like RXFP4 affinity and potency at human RXFP4. This minimized analogue was synthesized in 17.5-fold higher yield and in less time compared with hINSL5.

Published

2016

4. Structure of human insulin-like peptide 5 and characterization of conserved hydrogen bonds and electrostatic interactions within the relaxin framework.

Author

Haugaard-Jönsson LM, Hossain MA, Daly NL, Craik DJ, Wade JD, and Rosengren KJ

Subjects

Amino Acid Sequence, Humans, Hydrogen Bonding, Hydrogen-Ion Concentration, Insulin metabolism, Magnetic Resonance Spectroscopy, Models, Molecular, Molecular Sequence Data, Peptides chemical synthesis, Peptides chemistry, Protein Binding, Protein Structure, Secondary, Proteins metabolism, Receptors, G-Protein-Coupled metabolism, Receptors, Peptide metabolism, Solutions, Temperature, Titrimetry, Insulin chemistry, Proteins chemistry, Relaxin chemistry, Static Electricity

Abstract

INSL5 (insulin-like peptide 5) is a two-chain peptide hormone related to insulin and relaxin. It was recently discovered through searches of expressed sequence tag databases and, although the full biological significance of INSL5 is still being elucidated, high expression in peripheral tissues such as the colon, as well as in the brain and hypothalamus, suggests roles in gut contractility and neuroendocrine signalling. INSL5 activates the relaxin family peptide receptor 4 with high potency and appears to be the endogenous ligand for this receptor, on the basis of overlapping expression profiles and their apparent co-evolution. In the present study, we have used solution-state NMR to characterize the three-dimensional structure of synthetic human INSL5. The structure reveals an insulin/relaxin-like fold with three helical segments that are braced by three disulfide bonds and enclose a hydrophobic core. Furthermore, we characterized in detail the hydrogen-bond network and electrostatic interactions between charged groups in INSL5 by NMR-monitored temperature and pH titrations and undertook a comprehensive structural comparison with other members of the relaxin family, thus identifying the conserved structural features of the relaxin fold. The B-chain helix, which is the primary receptor-binding site of the relaxins, is longer in INSL5 than in its close relative relaxin-3. As this feature results in a different positioning of the receptor-activation domain Arg(B23) and Trp(B24), it may be an important contributor to the difference in biological activity observed for these two peptides. Overall, the structural studies provide mechanistic insights into the receptor selectivity of this important family of hormones.

Published

2009

5. Structural properties of relaxin chimeras.

Author

Haugaard-Jönsson LM, Hossain MA, Daly NL, Bathgate RA, Wade JD, Craik DJ, and Rosengren KJ

Subjects

Humans, Magnetic Resonance Spectroscopy, Protein Structure, Secondary, Recombinant Fusion Proteins chemical synthesis, Structure-Activity Relationship, Insulin chemistry, Proteins chemistry, Recombinant Fusion Proteins chemistry, Relaxin chemistry

Abstract

Relaxin-3 interacts with high potency with three relaxin family peptide receptors (RXFP1, RXFP3, and RXFP4). Therefore, the development of selective agonist and antagonist analogs is important for in vivo studies characterizing the biological significance of the different receptor-ligand systems and for future pharmaceutical applications. Recent reports demonstrated that a peptide selective for RXFP3 and RXFP4 over RXFP1 can be generated by the combination of the relaxin-3 B chain with the A chain from insulin-like peptide 5 (INSL5), creating an R3/I5 chimera. We have used NMR spectroscopy to determine the three-dimensional structure of this peptide to gain structural insights into the consequences of combining chains from two different relaxins. The R3/I5 structure reveals a similar backbone conformation for the relaxin-3 B chain compared to native relaxin-3, and the INSL5 A chain displays a relaxin/insulin-like fold with two parallel helices. The findings indicate that binding and activation of RXFP3 and RXFP4 mainly require the B chain and that the A chain functions as structural support. RXFP1, however, demonstrates a more complex binding mechanism, involving both the A chain and the B chain. The creation of chimeras is a promising strategy for generating new structure-activity data on relaxins.

Published

2009

6. Structure of the R3/I5 chimeric relaxin peptide, a selective GPCR135 and GPCR142 agonist.

Author

Haugaard-Jönsson LM, Hossain MA, Daly NL, Bathgate RA, Wade JD, Craik DJ, and Rosengren KJ

Subjects

Binding Sites, Humans, Nuclear Magnetic Resonance, Biomolecular, Protein Structure, Secondary, Receptors, G-Protein-Coupled chemistry, Receptors, Peptide chemistry, Structure-Activity Relationship, Insulin chemistry, Peptides chemistry, Proteins chemistry, Receptors, G-Protein-Coupled agonists, Receptors, Peptide agonists, Recombinant Fusion Proteins chemistry, Relaxin chemistry

Abstract

The human relaxin family comprises seven peptide hormones with various biological functions mediated through interactions with G-protein-coupled receptors. Interestingly, among the hitherto characterized receptors there is no absolute selectivity toward their primary ligand. The most striking example of this is the relaxin family ancestor, relaxin-3, which is an agonist for three of the four currently known relaxin receptors: GPCR135, GPCR142, and LGR7. Relaxin-3 and its endogenous receptor GPCR135 are both expressed predominantly in the brain and have been linked to regulation of stress and feeding. However, to fully understand the role of relaxin-3 in neurological signaling, the development of selective GPCR135 agonists and antagonists for in vivo studies is crucial. Recent reports have demonstrated that such selective ligands can be achieved by making chimeric peptides comprising the relaxin-3 B-chain combined with the INSL5 A-chain. To obtain structural insights into the consequences of combining A- and B-chains from different relaxins we have determined the NMR solution structure of a human relaxin-3/INSL5 chimeric peptide. The structure reveals that the INSL5 A-chain adopts a conformation similar to the relaxin-3 A-chain, and thus has the ability to structurally support a native-like conformation of the relaxin-3 B-chain. These findings suggest that the decrease in activity at the LGR7 receptor seen for this peptide is a result of the removal of a secondary LGR7 binding site present in the relaxin-3 A-chain, rather than conformational changes in the primary B-chain receptor binding site.

Published

2008

7. Synthesis, conformation, and activity of human insulin-like peptide 5 (INSL5).

Author

Akhter Hossain M, Bathgate RA, Kong CK, Shabanpoor F, Zhang S, Haugaard-Jönsson LM, Rosengren KJ, Tregear GW, and Wade JD

Subjects

Humans, Insulin chemistry, Protein Conformation, Proteins chemistry, Receptors, G-Protein-Coupled metabolism, Receptors, Peptide metabolism, Insulin chemical synthesis, Insulin metabolism, Proteins chemical synthesis, Proteins metabolism

Abstract

Insulin-like peptide 5 (INSL5) was first identified through searches of the expressed sequence tags (EST) databases. Primary sequence analysis showed it to be a prepropeptide that was predicted to be processed in vivo to yield a two-chain sequence (A and B) that contained the insulin-like disulfide cross-links. The high affinity interaction between INSL5 and the receptor RXFP4 (GPCR142) coupled with their apparent coevolution and partially overlapping tissue expression patterns strongly suggest that INSL5 is an endogenous ligand for RXFP4. Given that the primary function of the INSL5-RXFP4 pair remains unknown, an effective means of producing sufficient quantities of this peptide and its analogues is needed to systematically investigate its structural and biological properties. A combination of solid-phase peptide synthesis methods together with regioselective disulfide bond formation were used to obtain INSL5. Both chains were unusually resistant to standard synthesis protocols and required highly optimized conditions for their acquisition. In particular, the use of a strong tertiary amidine, DBU, as N(alpha)-deprotection base was required for the successful assembly of the B chain; this highlights the need to consider incomplete deprotection rather than acylation as a cause of failed synthesis. Following sequential disulfide bond formation and chain combination, the resulting synthetic INSL5, which was obtained in good overall yield, was shown to possess a similar secondary structure to human relaxin-3 (H3 relaxin). The peptide was able to inhibit cAMP activity in SK-N-MC cells that expressed the human RXFP4 receptor with a similar activity to H3 relaxin. In contrast, it had no activity on the human RXFP3 receptor. Synthetic INSL5 demonstrates equivalent activity to the recombinant-derived peptide, and will be an important tool for the determination of its biological function.

Published

2008

8. Solution structure and characterization of the LGR8 receptor binding surface of insulin-like peptide 3.

Author

Rosengren KJ, Zhang S, Lin F, Daly NL, Scott DJ, Hughes RA, Bathgate RA, Craik DJ, and Wade JD

Subjects

Amino Acid Sequence, Binding Sites, Hydrogen-Ion Concentration, Insulin physiology, Magnetic Resonance Spectroscopy, Molecular Sequence Data, Protein Structure, Quaternary, Proteins physiology, Solutions, Structure-Activity Relationship, Insulin chemistry, Proteins chemistry, Receptors, G-Protein-Coupled metabolism

Abstract

Insulin-like peptide 3 (INSL3), a member of the relaxin peptide family, is produced in testicular Leydig cells and ovarian thecal cells. Gene knock-out experiments have identified a key biological role in initiating testes descent during fetal development. Additionally, INSL3 has an important function in mediating male and female germ cell function. These actions are elicited via its recently identified receptor, LGR8, a member of the leucine-rich repeat-containing G-protein-coupled receptor family. To identify the structural features that are responsible for the interaction of INSL3 with its receptor, its solution structure was determined by NMR spectroscopy together with in vitro assays of a series of B-chain alanine-substituted analogs. Synthetic human INSL3 was found to adopt a characteristic relaxin/insulin-like fold in solution but is a highly dynamic molecule. The four termini of this two-chain peptide are disordered, and additional conformational exchange is evident in the molecular core. Alanine-substituted analogs were used to identify the key residues of INSL3 that are responsible for the interaction with the ectodomain of LGR8. These include Arg(B16) and Val(B19), with His(B12) and Arg(B20) playing a secondary role, as evident from the synergistic effect on the activity in double and triple mutants involving these residues. Together, these amino acids combine with the previously identified critical residue, Trp(B27), to form the receptor binding surface. The current results provide clear direction for the design of novel specific agonists and antagonists of this receptor.

Published

2006

9. Twists, knots, and rings in proteins. Structural definition of the cyclotide framework.

Author

Rosengren KJ, Daly NL, Plan MR, Waine C, and Craik DJ

Subjects

Amino Acid Sequence, Models, Molecular, Molecular Sequence Data, Nuclear Magnetic Resonance, Biomolecular, Protein Conformation, Sequence Homology, Amino Acid, Proteins chemistry

Abstract

In recent years an increasing number of miniproteins containing an amide-cyclized backbone have been discovered. The cyclotide family is the largest group of such proteins and is characterized by a circular protein backbone and six conserved cysteine residues linked by disulfide bonds in a tight core of the molecule. These form a cystine knot in which an embedded ring formed by two of the disulfide bonds and the connecting backbone segment is threaded by a third disulfide bond. In the current study we have undertaken high resolution structural analysis of two prototypic cyclotides, kalata B1 and cycloviolacin O1, to define the role of the conserved residues in the sequence. We provide the first comprehensive analysis of the topological features in this unique family of proteins, namely rings (a circular backbone), twists (a cis-peptide bond in the Möbius cyclotides) and knots (a knotted arrangement of the disulfide bonds).

Published

2003

10. Structural and Functional Characterization of the Conserved Salt Bridge in Mammalian Paneth Cell α-Defensins.

Author

Rosengren, K. Johan, Daly, Norelle L., Fornander, Liselotte M., Jönsson, Linda M. H., Shirafuji, Yoshinori, Xiaoqing Qu, Vogel, Hans J., Ouellette, Andre J., and Craik, David J.

Subjects

*PEPTIDES, *PROTEOLYTIC enzymes, *SALT, *IMMUNITY, *PROTEINS, *BIOMOLECULES

Abstract

α-Defensins are mediators of mammalian innate immunity, and knowledge of their structure-function relationships is essential for understanding their mechanisms of action. We report here the NMR solution structures of the mouse Paneth cell α-defensin cryptdin-4 (Crp4) and a mutant (E15D)-Crp4 peptide, in which a conserved Glu15 residue was replaced by Asp. Structural analysis of the two peptides confirms the involvement of this Glu in a conserved salt bridge that is removed in the mutant because of the shortened side chain. Despite disruption of this structural feature, the peptide variant retains a well defined native fold because of a rearrangement of side chains, which result in compensating favorable interactions. Furthermore, salt bridge-deficient Crp4 mutants were tested for bactericidal effects and resistance to proteolytic degradation, and all of the variants had similar bactericidal activities and stability to proteolysis. These findings support the conclusion that the function of the conserved salt bridge in Crp4 is not linked to bactericidal activity or proteolytic stability of the mature peptide. [ABSTRACT FROM AUTHOR]

Published

2006

11. Engineering stable peptide toxins by means of backbone cyclization: Stabilization of the α-conotoxin MII.

Author

Clark, Richard J., Fischer, Harald, Dempster, Louise, Daly, Norelle L., Rosengren, K. Johan, Nevin, Simon T., Meunier, Frederic A., Adams, David J., and Craik, David J.

Subjects

PEPTIDES, NEUROENDOCRINE cells, PIPIDAE, PROTEINS, ANTISENSE peptides, ACETYLCHOLINE

Abstract

Conotoxins (CTXs), with their exquisite specificity and potency, have recently created much excitement as drug leads. However, like most peptides, their beneficial activities may potentially be undermined by susceptibility to proteolysis in vivo. By cyclizing the α-ax MIl by using a range of linkers, we have engineered peptides that preserve their full activity but have greatly improved resis- tance to proteolytic degradation. The cyclic MIl analogue contain- ing a seven-residue linker joining the N and C termini was as active and selective as the native peptide for native and recombinant neuronal nicotinic acetylcholine receptor subtypes present in bo- vine chromaffin cells and expressed in Xenopus oocytes, respec- tively. Furthermore, its resistance to proteolysis against a specific protease and in human plasma was significantly improved. More generally, to our knowledge, this report is the first on the cycliza- tion of disulfide-rich toxins. Cyclization strategies represent an approach for stabilizing bioactive peptides while keeping their full potencies and should boost applications of peptide-based drugs in human medicine. [ABSTRACT FROM AUTHOR]

Published

2005