Insights into the role of protein molecule size and structure on interfacial properties using designed sequences

Dwyer, Mirjana Dimitrijev; He, Li; James, M. R.; Nelson, Andrew; Middelberg, Anton P. J.

doi:10.1098/rsif.2012.0987

Cited by 20 publications

(18 citation statements)

References 42 publications

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“…The observed adsorption kinetics of DAMP4 at pH 8.5 is consistent with the previous reported results of DAMP4 at pH 7.4 by Dwyer et al [24]. Results of Dwyer et al show that adsorption kinetics for DAMP4 at pH 7.4 is energy barrier-controlled, since the calculated experimental diffusion time constants are much larger than the theoretical values based on bulk diffusion.…”

Section: Mixing Damp4 and Sds To Improve Protein Foamssupporting

confidence: 94%

“…Reflectivity data of all four cycles fitted to a monolayer with a thickness of 15.8 ± 1 Å. This thickness is consistent with a single layer of DAMP4 determined previously by neutron reflectometry [24]. This confirms that the DAMP4 molecules unfold at the interface as a linear a-helical structure as opposed to its four-helix bundle in the bulk solution [13].…”

Section: Change Of Damp4 Surface Coverage Revealed By X-ray Reflectomsupporting

confidence: 81%

“…corresponds to the equilibrium surface tension for each system. The gap between starting and ending surface pressure is related to the energy barrier to desorb adsorbed molecules during compression [24]. These gaps are 8.6 mN/m in the absence of Zn 2+ and 15.2 mN/m in the presence of Zn 2+ .…”

Section: Foam Destabilization In the Presence Of Zinc Ionsmentioning

confidence: 99%

“…Small chemical surfactant molecules adsorb to the interface, within seconds, to achieve desired surface coverage and thus provide stable foams [20][21][22]. In contrast, due to their relatively large hydrodynamic molecular size and required structural changes at the interface, the adsorption of protein/peptide-based biosurfactants to interfaces normally takes tens of minutes, even hours to reach the equilibrium coverage [23,24]. In a study of a designed protein DAMP4 and its analogue DAMP1, Dwyer et al showed the adsorption of the larger molecule protein DAMP4 is accompanied with structural changes at the surface, and the adsorption kinetics is much slower than that of its smaller analogues DAMP1 [24].…”

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confidence: 98%

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Stabilizing and destabilizing protein surfactant-based foams in the presence of a chemical surfactant: Effect of adsorption kinetics

Agyei

Shen

et al. 2016

Journal of Colloid and Interface Science

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Stimuli-responsive protein surfactants promise alternative foaming materials that can be made from renewable sources. However, the cost of protein surfactants is still higher than their chemical counterparts. In order to reduce the required amount of protein surfactant for foaming, we investigated the foaming and adsorption properties of the protein surfactant, DAMP4, with addition of low concentrations of the chemical surfactant sodium dodecylsulfate (SDS). The results show that the small addition of SDS can enhance foaming functions of DAMP4 at a lowered protein concentration. Dynamic surface tension measurements suggest that there is a synergy between DAMP4 and SDS which enhances adsorption kinetics of DAMP4 at the initial stage of adsorption (first 60s), which in turn stabilizes protein foams. Further interfacial properties were revealed by X-ray reflectometry measurements, showing that there is a re-arrangement of adsorbed protein-surfactant layer over a long period of 1h. Importantly, the foaming switchability of DAMP4 by metal ions is not affected by the presence of SDS, and foams can be switched off by the addition of zinc ions at permissive pH. This work provides fundamental knowledge to guide formulation using a mixture of protein and chemical surfactants towards a high performance of foaming at a low cost.

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Section: Mixing Damp4 and Sds To Improve Protein Foamssupporting

confidence: 94%

Section: Change Of Damp4 Surface Coverage Revealed By X-ray Reflectomsupporting

confidence: 81%

Section: Foam Destabilization In the Presence Of Zinc Ionsmentioning

confidence: 99%

mentioning

confidence: 98%

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Stabilizing and destabilizing protein surfactant-based foams in the presence of a chemical surfactant: Effect of adsorption kinetics

Agyei

Shen

et al. 2016

Journal of Colloid and Interface Science

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“…This was attributed to the requirement for rearrangement of the larger and more structured DAMP4. 195 There have been few studies of PA or β-sheet peptide assembly at air/oil-water interfaces, with most reports instead focusing on their assembly in solution (Sections 1.2.1 and 1.2.2).…”

Section: Surfactantsmentioning

confidence: 99%

Bioproduction and self-assembly of designer peptides

Fletcher¹

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Self-assembly is a powerful method for producing controlled morphologies at the nanometre scale. Peptides are biomolecules capable of self-assembly and have the potential for use in a variety of applications such as emulsion and foam stabilisation, wound healing and drug delivery. The investigation of peptide sequence-structure relationships is a rapidly advancing field of study, which in many cases now allows the targeted design of self-assembling peptides.While self-assembling peptides show potential in several fields, their large-scale adoption is limited by the high production expenses associated with conventional solid-phase synthesis. A potentially cheaper and more renewable approach to peptide production is bacterial expression. However, the bioproduction of peptides is a non-trivial process, and generally involves the expression of peptides as part of a fusion protein in which the target peptide is only a small portion of the expressed product. An alternate approach involves peptide concatemers, in which the target peptide makes up the majority of the expressed construct.The work reported in this thesis focused on the design, characterisation and bioproduction of self-assembling α-helical peptides. It was particularly focussed on the development of amphiphillic α-helical peptides with applications as surfactants and hydrogelators. The aim of this work was to further the field of de novo peptide design, while also investigating an approach for peptide bioproduction. This work aimed to combine the requirements for peptide bioproduction with end-use functionality.Chapter 2 details successful bioproduction of an anionic helical surfactant peptide EDP-11, as part of a charge-paired heteroconcatemer with the cationic expression partner RDP-4. The method utilised designed assembly of the constituent α-helical peptides to generate a stably folded coiled-coil concatemer. The polypeptide sequence was further optimized for molecular charge, hydropathy and predicted protease resistance. This process allowed expression of a soluble concatemer that accumulated to high levels (22% of total protein) in E. coli. The expressed concatemer possessed extreme stability to heat and proteases, allowing isolation by simple heat and pH precipitation, yielding concatemer at 130 mg per gram of dry cell weight and >99% purity. Key parameters used in designing the heteroconcatemer were then compared to those of all open reading frames of several reference ii proteomes in an attempt to gain insight into the mechanistic basis for the high stability of the designed miniprotein.Following bioproduction using this concatemer approach, further processing was required to produce monomeric peptides for use in surfactant applications. The design of acid-cleavable aspartate-proline sites within the concatemer sequence allowed for simple heat-and acid-mediated cleavage to give constituent peptides.Chapter 3 details characterization of cleavage of the expressed concatemer by coupled liquid chromatography-mass spectrometry and includes mod...

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Receptor‐Specific Delivery of Protein Antigen to Dendritic Cells by a Nanoemulsion Formed Using Top‐Down Non‐Covalent Click Self‐Assembly

Zeng

Chuan

O’Sullivan

et al. 2013

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A new class of targeted and immune-evading nanocarrier made using only biological components and facile processes is assembled in a bottom-up fashion. Simple top-down sequential addition of immune-evading or receptor-specific antibody elements conjugated to biosurfactant protein DAMP4 promotes self-assembly at an interface previously formed in the presence of peptide surfactant AM1, leading to a functional display at the interface through non-covalent molecular self-assembly.

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Insights into the role of protein molecule size and structure on interfacial properties using designed sequences

Cited by 20 publications

References 42 publications

Stabilizing and destabilizing protein surfactant-based foams in the presence of a chemical surfactant: Effect of adsorption kinetics

Stabilizing and destabilizing protein surfactant-based foams in the presence of a chemical surfactant: Effect of adsorption kinetics

Bioproduction and self-assembly of designer peptides

Receptor‐Specific Delivery of Protein Antigen to Dendritic Cells by a Nanoemulsion Formed Using Top‐Down Non‐Covalent Click Self‐Assembly

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