Coarse-grained molecular dynamics studies of the structure and stability of peptide-based drug amphiphile filaments

Kang, Myungshim; Cui, Honggang; Loverde, Sharon M.

doi:10.1039/c7sm00943g

Cited by 19 publications

(30 citation statements)

References 93 publications

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“…In a subsequent simulation study, CG models are built based on AA simulation results, providing access to the µs-timescale molecular view on the assembly and disassembly processes. 95 These CG models successfully reproduce the growth of the molecular clusters and their elongation trends, compared with previously reported AA simulations. Furthermore the structure and the helicity of the ‘mCPT-buSS-Tau’ filaments are conserved in these CG simulations as shown in Figure 6.…”

Section: Simulation Of Drug Amphiphile Filamentssupporting

confidence: 60%

Molecular simulations of peptide amphiphiles

et al. 2017

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This review describes recent progress in the area of molecular simulations of peptide assemblies, including peptide-amphiphiles, and drug-amphiphiles. The ability to predict the structure and stability of peptide self-assemblies from the molecular level up is vital to the field of nanobiotechnology. Computational methods such as molecular dynamics offer the opportunity to characterize intermolecular forces between peptide-amphiphiles that are critical to the self-assembly process. Furthermore, these computational methods provide the ability to computationally probe the structure of these supramolecular assemblies at the molecular level, which is a challenge experimentally. Herein, we briefly highlight progress in the areas of all-atomistic and coarse-grained simulation studies investigating the self-assembly process of short peptides and peptide amphiphiles. We also discuss recent all-atomistic and coarse-grained simulations of the self-assembly of a drug-amphiphile into elongated filaments. Next, we discuss how these computational methods can provide further insight on the pathway of cylindrical nanofiber formation and predict their biocompatibility by studying the interaction of these peptide-amphiphile nanostructures with model cell membranes.

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Section: Simulation Of Drug Amphiphile Filamentssupporting

confidence: 60%

Molecular simulations of peptide amphiphiles

et al. 2017

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“…This differing arrangement of CPT molecules is a result of increased π–π interactions among individual CPT segments, as evidenced by excitonic coupling in the circular dichroism (CD) spectrum and molecular simulations. 193, 194 A later study by the same group, however, also suggests that the peptide segment could have an influence in nanotube formation as nanotubes were observed for a number of dCPT-based DAs. 195 By mixing of oppositely charged CPT drug amphiphiles (catanionic mixing), the Cui Lab reported on the formation of multiwalled nanotubes containing a fixed and high drug loading.…”

Section: Small Molecule Sapdsmentioning

confidence: 96%

Self-assembling prodrugs

et al. 2017

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Covalent modification of therapeutic compounds is a clinically proven strategy to devise prodrugs with enhanced treatment efficacies. This prodrug strategy relies on modified drugs that possess advantageous pharmacokinetic properties and administration routes over their parent drug. Self-assembling prodrugs represent an emerging class of therapeutic agents capable of spontaneously associating into well-defined supramolecular nanostructures in aqueous solutions. The self-assembly of prodrugs expands the functional space of conventional prodrug design, providing a possible pathway to more effective therapies as the assembled nanostructure possesses distinct physicochemical properties that can be tailored to specific administration routes and disease treatment. In this review, we will discuss the various types of self-assembling prodrugs in development, providing an overview of the methods used to control their structure and function and, ultimately, our perspective on their current and future potential.

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“…The Shinoda-Devane-Klein (SDK) model 23 is another CG force field that can be used for protein and peptide simulations, yet only non-bonded parameters were developed for the model and not bonded parameters (only generic bonded parameters were used in the parameterization of the model). Those who wish to use the SDK model thus may need to develop their own bonded parameters as in reference 46 . Regarding the non-bonded interactions, the softer LJ (9-6) potential form was used rather than the LJ (12-6) form shown in equation 1.…”

Section: Notable Protein Modelsmentioning

confidence: 99%

“…23 However, there is also an SDK CG water model that can be used in conjunction with the SDK protein model, in which parameters were developed for a CG water bead comprised of three water molecules. 46 43 The Martini model has a higher resolution for the side chains with up to four beads for a given amino acid. However, the backbone is modeled with just one bead per residue, and when using the Martini model, it is required that one specify the type of backbone bead-whether it is in an alpha helix or beta sheet or free in solution, for example.…”

Section: Notable Protein Modelsmentioning

confidence: 99%