Conformationally constrained human calcitonin (hCt) analogues reveal a critical role of sequence 17–21 for the oligomerization state and bioactivity of hCt

Kazantzis, Athanasios; Waldner, Michaela; Taylor, John W.; Kapurniotu, Aphrodite

doi:10.1046/j.0014-2956.2001.02689.x

Cited by 34 publications

(52 citation statements)

References 64 publications

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“…To test the ability to predict the effect of multiple amino acid substitutions on the aggregation rate of a polypeptide sequence, a series of short peptides were designed by using amino acids 10-21 of hCT as an initial template (these peptides are collectively named CT 10 -21 ). Studies on peptide fragments of hCT have suggested that residues in this region could play an important role in the activity and aggregation behavior of the full-length peptide (35,36). It has been shown in particular that five residues corresponding to positions 15-19 of hCT (DFNKF) play an active role in oligomerisation and fibril formation by hCT in vitro (35), and Lys-18 and Phe-19 have been identified as key residues in both the bioactivity and self-assembly of hCT (36).…”

Section: Resultsmentioning

confidence: 99%

Rational design of aggregation-resistant bioactive peptides: Reengineering human calcitonin

Fowler

Poon

Muff

et al. 2005

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

105

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A high propensity to aggregate into intractable deposits is a common problem limiting the production and use of many peptides and proteins in a wide range of biotechnological and pharmaceutical applications. Many therapeutic polypeptides are frequently abandoned at an early stage in their development because of problems with stability and aggregation. It has been shown recently that parameters describing the physicochemical properties of polypeptides can be used as predictors of protein aggregation. Here we demonstrate that these and similar tools can be applied to the rational redesign of bioactive molecules with a significantly reduced aggregation propensity without loss of physiological activity. This strategy has been exemplified by designing variants of the hormone calcitonin that show a significantly reduced aggregation propensity, yet maintain, or even increase, their potency when compared to the current therapeutic forms. The results suggest that this approach could be used successfully to enhance the solubility and efficacy of a wide range of other peptide and protein therapeutics.protein aggregation ͉ protein design ͉ biopharmaceuticals ͉ amyloid ͉ misfolding T he number of pharmacologically active peptides and proteins under development for the prevention and treatment of human disorders is increasing, and as a result, so is the pressure to overcome problems associated with aggregation and stability. Up to 96% of all drug candidates in trials are abandoned during preclinical or clinical development, often because of low solubility or aggregation problems (1). Many peptide-based drugs with great therapeutic potential are rendered ineffective simply because of an intrinsic propensity to aggregate irreversibly (2). Aggregation is one of the most significant obstacles to the development of protein-based drugs because it cannot only compromise their bioavailability and therapeutic activity but it may also increase the risk of immunogenic reactions (3, 4).A good example of a bioactive peptide with limited pharmaceutical potential due to a high tendency to aggregate is human calcitonin (hCT), a 32-residue polypeptide hormone synthesized and secreted by the C cells of the thyroid, and involved in calcium regulation and bone dynamics. In vivo, calcitonin (CT) causes a rapid, but short-lived, decline in calcium and phosphate levels in the blood by promoting the incorporation of these ions into bone (5). This activity has lead to the use of CT in the treatment of conditions such as osteoporosis and Paget's disease, as well as malignancy-caused hypercalcemia and musculoskeletal pain (5-7). However, hCT shows an extremely high tendency to selfassociate in the form of amyloid fibrils. As a result hCT amyloid deposits can occur in vivo in patients with medullar carcinoma of the thyroid (8, 9) and in vitro in preparations designed for patient administration (10). Not only does aggregation constitute a serious problem during the production, storage, and administration of hCT, but it can also lead to a significant decr...

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Section: Resultsmentioning

confidence: 99%

Rational design of aggregation-resistant bioactive peptides: Reengineering human calcitonin

Fowler

Poon

Muff

et al. 2005

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

105

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“…For this, we used an in silico approach applying the Waltz software (23). We first tested the software on hCT and sCT wild-type sequences, which were recognized as fibril-forming and aggregation-resistant according to reported experimental findings (11 (38,39) and the C-terminal region previously suggested as the fibril core (22,39,40).…”

Section: Resultsmentioning

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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“…Cell Culture-Human breast cancer T 47D cells were cultured as described (20) in RPMI 1640 containing 10% heat inactivated fetal bovine serum, 1% streptomycin/penicillin, 0.1 M insulin, and 0.1 M hydrocortisone in 5% CO 2 and 310 K. The latter hormones were omitted from the medium when subculturing cells to be used 1-3 days later for the receptor binding assay. Subculturing was performed with trypsin/EDTA as described (41,42), and for the binding experiments cells were subcultured in 12-well dishes. Receptor binding experiments were performed when cells reached 90% confluence (1-3 days after subculture).…”

Section: Methodsmentioning

confidence: 99%

“…Receptor Binding Assay-The assay was performed according to established protocols (41)(42). Briefly, cells in the 12-well dishes were washed with NaCl/P i (1 ml) at room temperature, and then prewarmed (310 K) assay buffer (RPMI 1640 and 0.1% (w/v) bovine serum albumin) was added to the cells (950 l).…”

Section: Methodsmentioning

confidence: 99%

Structural Determinants of Salmon Calcitonin Bioactivity

Andreotti

Méndez

Amodeo

et al. 2006

Journal of Biological Chemistry

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Salmon calcitonin (sCT) forms an amphipathic helix in the region 9-19, with the C-terminal decapeptide interacting with the helix (Amodeo, P., Motta, A., Strazzullo, G., Castiglione Morelli, M. A. (1999) J. Biomol. NMR 13, 161-174). To uncover the structural requirements for the hormone bioactivity, we investigated several sCT analogs. They were designed so as to alter the length of the central helix by removal and/or replacement of flanking residues and by selectively mutating or deleting residues inside the helix. The helix content was assessed by circular dichroism and NMR spectroscopies; the receptor binding affinity in human breast cancer cell line T 47D and the in vivo hypocalcemic activity were also evaluated. In particular, by NMR spectroscopy and molecular dynamics calculations we studied Leu 23,Ala 24-sCT in which Pro 23 and Arg 24 were replaced by helix inducing residues. Compared with sCT, it assumes a longer amphipathic ␣-helix, with decreased binding affinity and one-fifth of the hypocalcemic activity, therefore supporting the idea of a relationship between a definite helix length and bioactivity. From the analysis of other sCT mutants, we inferred that the correct helix length is located in the 9-19 region and requires long range interactions and the presence of specific regions of residues within the sequence for high binding affinity and hypocalcemic activity. Taken together, the structural and biological data identify well defined structural parameters of the helix for sCT bioactivity.The most recognized action of calcitonin (CT) 4 is the inhibition of osteoclast-mediated bone resorption. This forms the basis for its primary clinical use in the treatment of bone-related disorders such as Paget disease, osteoporosis, and hypercalcemia of malignancy (1). CT activity also includes modulation of renal ion excretion, analgesia, inhibition of appetite, and gastric acid secretion as well as influence on reproduction via the effects on embryological implantation and sperm function (Ref. 1 and references therein). Recently, CT has been put forward as an ideal agent for treatment of osteoarthritis (2).CT is a single-chain polypeptide hormone of 32 amino acids with an N-terminal disulfide bridge between positions 1 and 7 and a C-terminal amidated proline. CT species so far studied can be subdivided into three major classes: human/rodent, artiodactyl, and teleost/avian; of these, the members of the teleost/avian group are generally the most potent, although relative potency varies in a species-and isoform-specific manner (3). The higher potency combined with a longer in vivo halflife has led to fish-like CT, exemplified by salmon CT (sCT), as the standard form of CT used for the clinical treatment of bone disorders (4). However, the usefulness of CT is limited by the development of clinical resistance. This can be due to development of circulating antibodies against non-human CT (5) and/or loss of responsiveness to CT, presumably via receptor down-regulation and inhibition of new receptor synthesis (6). ...

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Conformationally constrained human calcitonin (hCt) analogues reveal a critical role of sequence 17–21 for the oligomerization state and bioactivity of hCt

Cited by 34 publications

References 64 publications

Rational design of aggregation-resistant bioactive peptides: Reengineering human calcitonin

Rational design of aggregation-resistant bioactive peptides: Reengineering human calcitonin

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

Structural Determinants of Salmon Calcitonin Bioactivity

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