α-Helix targeting reduces amyloid-β peptide toxicity

Nerelius, Charlotte; Sandegren, Anna; Sargsyan, Hasmik; Raunak, R.; Leijonmarck, Hans; Chatterjee, Urmimala; Fisahn, André; Imarisio, Sara; Lomas, David A.; Crowther, Damian C.; Strömberg, Roger; Johansson, Jan

doi:10.1073/pnas.0810364106

Cited by 129 publications

(157 citation statements)

References 37 publications

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“…Most likely an efficient stabilization should lock the molecule in the socalled "␣-basin" (a free energy surface dominated by ␣-helical structures with minima of comparable free energies separated by low barriers (72)), avoiding the migration toward the "␤-basin." Such ␣-helix 3 ␤-sheet conversion going through progressively looser helical segments can be hampered by targeting either the intact ␣-helix with ligand molecules (73) or the structurally independent folding units (turnlike structures) present in the peptide (72,74). The presence of SDS, used as a helix stabilizer, does lengthen the fibrillation time (the lag time of the onset of fibrillation) but does not abolish hCT aggregation.…”

Section: Discussionmentioning

confidence: 99%

Converting the Highly Amyloidogenic Human Calcitonin into a Powerful Fibril Inhibitor by Three-dimensional Structure Homology with a Non-amyloidogenic Analogue

Andreotti

Vitale

Avidan-Shpalter

et al. 2011

Journal of Biological Chemistry

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Irreversible aggregation limits bioavailability and therapeutic activity of protein-based drugs. Here we show that an aggregation-resistant mutant can be engineered by structural homology with a non-amyloidogenic analogue and that the aggregation-resistant variant may act as an inhibitor. This strategy has successfully been applied to the amyloidogenic human calcitonin (hCT). Including only five residues from the non-amyloidogenic salmon calcitonin (sCT), we obtained a variant, polar human calcitonin (phCT), whose solution structure was shown by CD, NMR, and calculations to be practically identical to that of sCT. phCT was also observed to be a potent amyloidogenesis inhibitor of hCT when mixed with it in a 1:1 ratio. Fibrillation studies of phCT and the phCT-hCT mixture mimicked the sCT behavior in the kinetics and shapes of the fibrils with a dramatic reduction with respect to hCT. Finally, the effect of phCT alone and of the mixture on the intracellular cAMP level in T47D cells confirmed for the mutant and the mixture their calcitonin-like activity, exhibiting stimulation effects identical to those of sCT, the current therapeutic form. The strategy followed appears to be suitable to develop new forms of hCT with a striking reduction of aggregation and improved activity. Finally, the inhibitory properties of the aggregation-resistant analogue, if confirmed for other amyloidogenic peptides, may favor a new strategy for controlling fibril formation in a variety of human diseases.The intrinsic propensity of peptides and proteins to irreversibly aggregate limits the development of protein-based drugs because aggregation compromises their bioavailability and therapeutic activity and increases the risk of immunogenic reactions (1, 2). Possible strategies for overcoming these problems involve the design of specific analogues in which the physicochemical properties of the molecule are changed through mutations of a small number of amino acids (3) or the development of safe inhibitors such as small peptide fragments (4 -6). However, because at the moment large molar excesses of inhibitors are used, their pharmacological efficacy appears to be of limited relevance.A good example of a bioactive peptide with limited pharmaceutical potential due to a high tendency to aggregate is human calcitonin (hCT).3 It is a 32-residue hormone synthesized and secreted by the C cells of the thyroid and involved in calcium regulation and bone dynamics (7). In its common form it presents an N-terminal disulfide bridge between positions 1 and 7 and a C-terminal proline amide residue. Only eight residues are common to all species so far studied, and these are clustered at the two ends of the molecule. The salmon variant (sCT) is widely used in the treatment of osteoporosis and Paget disease as well as malignancy-caused hypercalcemia and musculoskeletal pain (8,9). This is because hCT shows an extremely high tendency to form amyloid fibrils both in vivo in patients with medullar carcinoma of the thyroid (10) and in vitro in preparations desi...

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Section: Discussionmentioning

confidence: 99%

Converting the Highly Amyloidogenic Human Calcitonin into a Powerful Fibril Inhibitor by Three-dimensional Structure Homology with a Non-amyloidogenic Analogue

Andreotti

Vitale

Avidan-Shpalter

et al. 2011

Journal of Biological Chemistry

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“…For example, the ability of KW1AP to discriminate between different types of Aβ oligomers (Fig. 2F) could give rise to highly targeted applications to ascertain the contribution of specific Aβ assemblies to pathogenicity using in vivo systems that facilitate analysis of protein modifiers of aggregation (42,43).…”

Section: Discussionmentioning

confidence: 99%

Molecular basis of β-amyloid oligomer recognition with a conformational antibody fragment

Morgado

Wieligmann

Bereza

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

103

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Oligomers are intermediates of the β-amyloid (Aβ) peptide fibrillogenic pathway and are putative pathogenic culprits in Alzheimer's disease (AD). Here we report the biotechnological generation and biochemical characterization of an oligomer-specific antibody fragment, KW1. KW1 not only discriminates between oligomers and other Aβ conformations, such as fibrils or disaggregated peptide; it also differentiates between different types of Aβ oligomers, such as those formed by Aβ (1-40) and Aβ (1-42) peptide. This high selectivity of binding contrasts sharply with many other conformational antibodies that interact with a large number of structurally analogous but sequentially different antigens. X-ray crystallography, NMR spectroscopy, and peptide array measurements imply that KW1 recognizes oligomers through a hydrophobic and significantly aromatic surface motif that includes Aβ residues 18-20. KW1-positive oligomers occur in human AD brain samples and induce synaptic dysfunctions in living brain tissues. Bivalent KW1 potently neutralizes this effect and interferes with Aβ assembly. By altering a specific step of the fibrillogenic cascade, it prevents the formation of mature Aβ fibrils and induces the accumulation of nonfibrillar aggregates. Our data illuminate significant mechanistic differences in oligomeric and fibril recognition and suggest the considerable potential of KW1 in future studies to detect or inhibit specific types of Aβ conformers.camelid antibody fragments | protein aggregation | immunotherapy

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“…The structure of the carboxyl terminus may involve novel metastable conformations (b-hairpin at 35 -37), but these remain to be confirmed by crystallographic methods . Synthetic oligomers are also being used in attempts to discover small molecules which are able to target these specific assemblies (Davis and Berkowitz 2009a;Davis et al 2009;Feng et al 2009;Liu et al 2009a;Nerelius et al 2009;Pitt et al 2009;Riviere et al 2009;Smith et al 2009;Sun et al 2009;Yamin et al 2009;Hawkes et al 2010;Ladiwala et al 2010). …”

Section: Molecular Dynamic Approaches To Understanding Synthetic Ab Omentioning

confidence: 99%

Biochemistry of Amyloid -Protein and Amyloid Deposits in Alzheimer Disease

Masters

Selkoe²

2012

Cold Spring Harbor Perspectives in Medicine

491

405

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α-Helix targeting reduces amyloid-β peptide toxicity

Cited by 129 publications

References 37 publications

Converting the Highly Amyloidogenic Human Calcitonin into a Powerful Fibril Inhibitor by Three-dimensional Structure Homology with a Non-amyloidogenic Analogue

Converting the Highly Amyloidogenic Human Calcitonin into a Powerful Fibril Inhibitor by Three-dimensional Structure Homology with a Non-amyloidogenic Analogue

Molecular basis of β-amyloid oligomer recognition with a conformational antibody fragment

Biochemistry of Amyloid -Protein and Amyloid Deposits in Alzheimer Disease

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