Biomimicry of Surfactant Protein C

Overview

Journal Acc Chem Res

Specialty Chemistry

Date 2008 Oct 7

PMID 18834153

Citations 5

Authors

Nathan J Brown

Jan Johansson

Annelise E Barron

Affiliations

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Abstract

Since the widespread use of exogenous lung surfactant to treat neonatal respiratory distress syndrome, premature infant survival and respiratory morbidity have dramatically improved. Despite the effectiveness of the animal-derived surfactant preparations, there still remain some concerns and difficulties associated with their use. This has prompted investigation into the creation of synthetic surfactant preparations. However, to date, no clinically used synthetic formulation is as effective as the natural material. This is largely because the previous synthetic formulations lacked analogues of the hydrophobic proteins of the lung surfactant system, SP-B and SP-C, which are critical functional constituents. As a result, recent investigation has turned toward the development of a new generation of synthetic, biomimetic surfactants that contain synthetic phospholipids along with a mimic of the hydrophobic protein portion of lung surfactant. In this Account, we detail our efforts in creating accurate mimics of SP-C for use in a synthetic surfactant replacement therapy. Despite SP-C's seemingly simple structure, the predominantly helical protein is extraordinarily challenging to work with given its extreme hydrophobicity and structural instability, which greatly complicates the creation of an effective SP-C analogue. Drawing inspiration from Nature, two promising biomimetic approaches have led to the creation of rationally designed biopolymers that recapitulate many of SP-C's molecular features. The first approach utilizes detailed SP-C structure-activity relationships and amino acid folding propensities to create a peptide-based analogue, SP-C33. In SP-C33, the problematic and metastable polyvaline helix is replaced with a structurally stable polyleucine helix and includes a well-placed positive charge to prevent aggregation. SP-C33 is structurally stable and eliminates the association propensity of the native protein. The second approach follows the same design considerations but makes use of a non-natural, poly-N-substituted glycine or "peptoid" scaffold to circumvent the difficulties associated with SP-C. By incorporating unique biomimetic side chains in a non-natural backbone, the peptoid mimic captures both SP-C's hydrophobic patterning and its helical secondary structure. Despite the differences in structure, both SP-C33 and the SP-C peptoid mimic capture many requisite features of SP-C. In a surfactant environment, these analogues also replicate many of the key surface activities necessary for a functional biomimetic surfactant therapy while overcoming the difficulties associated with the natural protein. With improved stability, greater production potential, and elimination of possible pathogenic contamination, these biomimetic surfactant formulations offer not only the potential to improve the treatment of respiratory distress syndrome but also the opportunity to treat other respiratory-related disorders.

Citing Articles

Helical side chain chemistry of a peptoid-based SP-C analogue: Balancing structural rigidity and biomimicry.

Brown N, Lin J, Barron A Biopolymers. 2019; 110(6):e23277.

PMID: 30972750 PMC: 6661009. DOI: 10.1002/bip.23277.

Peptoids and polyamines going sweet: Modular synthesis of glycosylated peptoids and polyamines using click chemistry.

Furniss D, Mack T, Hahn F, Vollrath S, Koroniak K, Schepers U Beilstein J Org Chem. 2013; 9:56-63.

PMID: 23399592 PMC: 3566861. DOI: 10.3762/bjoc.9.7.

Biomimetic N-terminal alkylation of peptoid analogues of surfactant protein C.

Brown N, Dohm M, Bernardino de la Serna J, Barron A Biophys J. 2011; 101(5):1076-85.

PMID: 21889444 PMC: 3164185. DOI: 10.1016/j.bpj.2011.04.055.

Solid-phase synthesis of N-substituted glycine oligomers (alpha-peptoids) and derivatives.

Culf A, Ouellette R Molecules. 2010; 15(8):5282-335.

PMID: 20714299 PMC: 6257730. DOI: 10.3390/molecules15085282.

The Brichos domain of prosurfactant protein C can hold and fold a transmembrane segment.

Johansson H, Eriksson M, Nordling K, Presto J, Johansson J Protein Sci. 2009; 18(6):1175-82.

PMID: 19472327 PMC: 2774428. DOI: 10.1002/pro.123.

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