Fude Sun

Role of peptide self-assembly in antimicrobial peptides†

Antimicrobial peptides (AMPs) are considered as potential antibiotic substitutes because of their potent activities. Previous studies mainly focused on the effects of peptide charges and secondary structures, but the self‐assembly of AMPs was neglected. As more and more researchers notice the roles of peptide self‐assembly in AMPs, it has been considered as another important property. In this review, we will discuss the influences of peptide self‐assembly on the activity and mode of action, and some specific features it introduces to the AMPs, such as particular responsiveness, improved cell selectivity and stability and sustained release. In addition, some methods to design self‐assembling AMPs are primarily discussed. With further understanding about the self‐assembling regularity, design of particular self‐assembling AMPs will be very helpful for their applications, especially in the fields of drug delivery and biomedical engineering. Copyright

Insights into the Packing Switching of the EphA2 Transmembrane Domain by Molecular Dynamic Simulations

Receptor tyrosine kinases play an important role in mediating cell migration and adhesion associated with various biology processes. With a single-span transmembrane domain (TMD), the activities of the receptors are regulated by the definite packing configurations of the TMDs. For the EphA2 receptor, increasing studies have been conducted to investigate the packing domains that induce its switching TMD dimerization. However, the inherent transformation mechanisms including the interrelations among the involved packing domains remain unclear. Herein, we applied multiple simulation methods to explore the underlying packing mechanisms within the EphA2 TMD dimer. Our results demonstrated that the G(540)xxxG(544) contributed to the formation of the right-handed configuration while the heptad repeat L(535)xxxG(539)xxA(542)xxxV(546)xxL(549)xxxG(553) motif together with the FFxH(559) region mediated the parallel mode. Furthermore, the FF(557) residues packing mutually as rigid riveting structures were found comparable to the heptad repeat motif in maintaining the parallel configuration. In addition, the H(559) residue associated definitely with the lower bilayer leaflet, which was proved to stabilize the parallel mode significantly. The simulations provide a full range of insights into the essential packing motifs or residues involved in the switching TMD dimer configurations, which can enrich our comprehension toward the EphA2 receptor.

Dimerization and Structural Stability of Amyloid Precursor Proteins Affected by the Membrane Microenvironments

The lipid raft microenvironment is implicated in the generation of the pathological amyloid-β (Aβ) species in amyloid precursor protein (APP) that is associated with neurodegenerative diseases. Evidence shows that APP forms a transmembrane homodimer with changeable structures as a function of the membrane compositions. However, the molecular responsibility of the dimerization and structural alteration for the amyloidogenic process in segregated membranes remains largely unclear. Here, we performed multiple coarse grained (CG) simulations to explore the behavioral preference of the transmembrane domain of APP (called C99) that is affected by the lipid raft microenvironment. The results showed that C99 was anchored at the boundary of the lipid raft relying on the conserved hydrophobic motif of V710xxA713xxxV717xxxV721. Moreover, the dimerization of C99 was greatly destabilized by the lipid raft, which led to a susceptible switching packing conformation. The molecular driving forces were derived from the combined regulation of the saturated lipids and cholesterols rather than from the simple binding competition of cholesterol in the C99 dimerization. The molecular details of the differential dimerization in the raft-forming and bulk fluid bilayer environments were compared, and the structural information was helpful for further understanding the enzymolysis responsiveness of APP.

Molecular Dynamic Simulation of the Self-Assembly of DAP12-NKG2C Activating Immunoreceptor Complex

The DAP12-NKG2C activating immunoreceptor complex is one of the multisubunit transmembrane protein complexes in which ligand-binding receptor chains assemble with dimeric signal-transducing modules through non-covalent associations in their transmembrane (TM) domains. In this work, both coarse grained and atomistic molecular dynamic simulation methods were applied to investigate the self-assembly dynamics of the transmembrane domains of the DAP12-NKG2C activating immunoreceptor complex. Through simulating the dynamics of DAP12-NKG2C TM heterotrimer and point mutations, we demonstrated that a five-polar-residue motif including: 2 Asps and 2 Thrs in DAP12 dimer, as well as 1 Lys in NKG2C TM plays an important role in the assembly structure of the DAP12-NKG2C TM heterotrimer. Furthermore, we provided clear evidences to exclude the possibility that another NKG2C could stably associate with the DAP12-NKG2C heterotrimer. Based on the simulation results, we proposed a revised model for the self-assembly of DAP12-NKG2C activating immunoreceptor complex, along with a plausible explanation for the association of only one NKG2C with a DAP12 dimer.

Critical Residues and Motifs for Homodimerization of the First Transmembrane Domain of the Plasma Membrane Glycoprotein CD36

The plasma transmembrane (TM) glycoprotein CD36 is critically involved in many essential signaling processes, especially the binding/uptake of long-chain fatty acids and oxidized low-density lipoproteins. The association of CD36 potentially activates cytosolic protein tyrosine kinases that are thought to associate with the C-terminal cytoplasmic tail of CD36. To understand the mechanisms by which CD36 mediates ligand binding and signal transduction, we have characterized the homo-oligomeric interaction of CD36 TM domains in membrane environments and with molecular dynamics (MD) simulations. Analysis of pyrene- and coumarin-labeled TM1 peptides in SDS by FRET confirmed the homodimerization of the CD36 TM1 peptide. Homodimerization assays of CD36 TM domains with the TOXCAT technique showed that its first TM (TM1) domain, but not the second TM (TM2) domain, could homodimerize in a cell membrane. Small-residue, site-specific mutation scanning revealed that the CD36 TM1 dimerization is mediated by the conserved small residues Gly12, Gly16, Ala20, and Gly23. Furthermore, molecular dynamics (MD) simulation studies demonstrated that CD36 TM1 exhibited a switching dimerization with two right-handed packing modes driven by the 12GXXXGXXXA20 and 20AXXG23 motifs, and the mutational effect of G16I and G23I revealed these representative conformations of CD36 TM1. This packing switch pattern of CD36 TM1 homodimer was further examined and confirmed by FRET analysis of monobromobimane (mBBr)-labeled CD36 TM1 peptides. Overall, this work provides a structural basis for understanding the role of TM association in regulating signal transduction via CD36.

Insights into the transmembrane helix associations of kit ligand by molecular dynamics simulation and TOXCAT

Kit ligand (KITL) plays important roles in cell proliferation, differentiation, and survival via interaction with its receptor Kit. The previous studies demonstrated that KITL formed a noncovalent homodimer through transmembrane (TM) domain; however, the undergoing mechanism of transmembrane association that determines KITL TM dimerization is still not clear. Herein, molecular dynamics (MD) simulation strategy and TOXCAT assay were combined to characterize the dimerization interface and structure of KITL TM in details. KITL TM formed a more energetically favorable noncovalent dimer through a conserved SxxxGxxxG motif in the MD simulation. Furthermore, the TOXCAT results demonstrated that KITL TM self‐associated strongly in the bilayer membrane environment. Mutating any one of the small residues Ser11, Gly15 or Gly19 to Ile disrupted KITL TM dimerization dramatically, which further validated our MD simulation results. In addition, our results showed that Tyr22 could help to stabilize the TM interactions via interacting with the phosphoric group in the bilayer membrane. Pro7 did not induce helix kinks or swivel angles in KITL TM, but it was related with the pitch of the turn around this residue so as to affect the dimer formation. Combining the results of computer modeling and experimental mutagenesis studies on the KITL TM provide new insights for the transmembrane helix association of KITL dimerization. Proteins 2017; 85:1362–1370.

High-Resolution Insights into the Stepwise Self-Assembly of Nanofiber from Bioactive Peptides

Peptide self-assembly has a profound biological significance since self-assembled bioactive peptides are gifted with improved bioactivity as well as life-span. In this study, peptide self-assembly was investigated using a therapeutic peptide, PTP-7S (EENFLGALFKALSKLL). Combining experiments of atomic force microscopy (AFM), circular dichroism (CD), and 8-anilino-1-naphthalenesulfonic acid (ANS) fluorescence spectra, PTP-7S showed the α-helical structure and was found self-assembling into nanofibers in solution. Relying on the coarse-grained (CG) dynamic simulations, the self-assembling of PTP-7S was revealed as a stepwise process that peptide monomers first clustered into peptide-assembling units (PUs) with charged surface, and then the PUs integrated together to construct nanofibril aggregates. Different roles of the nonbonded driving forces did play in the two phases: the hydrophobic force and electrostatic interaction acted as the predominant motivations in the formation of PUs and nanofiber, respectively. Moreover, the electrostatic interaction helped to guide the longitudinal growth of peptide nanofibers. A sequence principle is proposed for peptide self-assembling in aqueous solution: a balance of the counter charges and sufficient hydrophobicity degree. The self-assembled PTP-7S displayed good anticancer activity, proteases resistance, and sustained drug-release, showing a great potential for clinical application. This study reveals the molecular mechanism in explaining PTP-7S self-assembly and it is beneficial for future innovation of the self-assembled bioactive peptides.

New amphiphilic N-phosphoryl oligopeptides designed for gene delivery.

Gene therapy is a potent tool for the treatment of cancer and other gene defect diseases, which involves using DNA that encodes a functional, therapeutic gene to replace a mutated gene. However, the DNA transfection efficiency is restricted by its negative charges and low susceptibility to endonucleases which prevent them penetrating tissue and cellular membranes. Both viral and non-viral vectors have been used for gene delivery, but the former are limited by their immunogenicity, while the latter are less efficient than their viral counterpart. Cationic amphiphilic lipopeptides whose structures can be easily modified and transformed have been used as non-viral vectors in gene delivery system due to their low cytotoxicity and high transfection efficiency. In this study, a series of cationic amphiphilic N-phosphoryl oligopeptides with varied lengths of hydrophobic tails and oligopeptide headgroups (C12-K6, C14-K6, C16-K6, Chol-K6 and C12-H6) were synthesized and used as gene delivery vectors. The affinities, abilities to condense pDNA and transfection efficiencies of the K6-lipopeptides were better than those of the H6-lipopeptides. In addition, the hydrophobic chains of the lipopeptides also affected their transfection efficiencies. The K6-lipopeptide with a hydrophobic chain of twelve carbons (C12-K6) showed the highest transfection efficiency in all these synthetic lipopeptides. At an optimal P/N ratio of 20, C12-K6 showed comparable pDNA transfection efficiency to PEI-25k, a well-defined gene delivery vector, but the cytotoxicity of C12-K6 was much lower. With acceptable gene transfection efficiency and low cytotoxicity, this cationic amphiphilic lipopeptide will have promising applications in gene therapy.

The dimerization of PSGL-1 is driven by the transmembrane domain via a leucine zipper motif

P‐selectin glycoprotein ligand‐1 (PSGL‐1) is a homodimeric mucin ligand that is important to mediate the earliest adhesive event during an inflammatory response by rapidly forming and dissociating the selectin‐ligand adhesive bonds. Recent research indicates that the noncovalent associations between the PSGL‐1 transmembrane domains (TMDs) can substitute for the C320‐dependent covalent bond to mediate the dimerization of PSGL‐1. In this article, we combined TOXCAT assays and molecular dynamics (MD) simulations to probe the mechanism of PSGL‐1 dimerization. The results of TOXCAT assays and Martini coarse‐grained molecular dynamics (CG MD) simulations demonstrated that PSGL‐1 TMDs strongly dimerized in a natural membrane and a leucine zipper motif was responsible for the noncovalent dimerization of PSGL‐1 TMD since mutations of the residues that occupied a or d positions in an (abcdefg)n leucine heptad repeat motif significantly reduced the dimer activity. Furthermore, we studied the effects of the disulfide bond on the PSGL‐1 dimer using MD simulations. The disulfide bond was critical to form the leucine zipper structure, by which the disulfide bond further improved the stability of the PSGL‐1 dimer. These findings provide insights to understand the transmembrane association of PSGL‐1 that is an important structural basis for PSGL‐1 preferentially binding to P‐selectin to achieve its biochemical and biophysical functions.