Weiyue Lu

Cyclic RGD conjugated poly(ethylene glycol)-co-poly(lactic acid) micelle enhances paclitaxel anti-glioblastoma effect

The use of glioblastoma-targeted drug delivery system facilitates efficient delivery of chemotherapeutic agents to malignant gliomas in the central nervous system while minimizing high systemic doses associated with debilitating toxicities. To employ the high binding affinity of a cyclic RGD peptide (c(RGDyK), cyclic Arginine-Glycine-Aspartic acid-D-Tyrosine-Lysine) with integrin alpha(v)beta(3) over-expressed on tumor neovasculature and U87MG glioblastoma cells, we prepared paclitaxel-loaded c(RGDyK)-Poly(ethylene glycol)-block-poly(lactic acid) micelle (c(RGDyK)-PEG-PLA-PTX). In vitro physicochemical characterization of these novel micelles showed satisfactory encapsulated efficiency, loading capacity and size distribution. In vitro cytotoxicity studies proved that the presence of c(RGDyK) enhanced the anti-glioblastoma cell cytotoxic efficacy by 2.5 folds. The binding affinity of c(RGDyK)-PEG-PLA micelle with U87MG cells was also investigated. The competitive binding IC(50) value of c(RGDyK)-PEG-PLA micelle was 26.30 nM, even lower than that of c(RGDyK) (56.23 nM). In U87MG glioblastoma-bearing nude mice model, biodistribution of (125)I-radiolabeled c(RGDyK)-PEG-PLA or DiR encapsulated micelles and anti-glioblastoma pharmacological effect was investigated after intravenous administration. c(RGDyK)-PEG-PLA micelle accumulated in the subcutaneous and intracranial tumor tissue, and when loaded with PTX (c(RGDyK)-PEG-PLA-PTX), exhibited the strongest tumor growth inhibition among the studied paclitaxel formulations. The anti-glioblastoma effect of c(RGDyK)-PEG-PLA-PTX micelle was also reflected in the median survival time of mice bearing intracranial U87MG tumor xenografts where the median survival time of c(RGDyK)-PEG-PLA-PTX micelle-treated mice (48 days) was significantly longer than that of mice treated with PEG-PLA-PTX micelle (41.5 days), Taxol (38.5 days) or saline (34 days). Therefore, our results suggested that c(RGDyK)-PEG-PLA micelle may be a potential drug delivery system in the treatment of integrin alpha(v)beta(3) over-expressed glioblastoma.

Two-order targeted brain tumor imaging by using an optical/paramagnetic nanoprobe across the blood brain barrier

Surgical resection is a mainstay of brain tumor treatments. However, the completed excision of malignant brain tumor is challenged by its infiltrative nature. Contrast enhanced magnetic resonance imaging is widely used for defining brain tumor in clinic. However its ability in tumor visualization is hindered by the transient circulation lifetime, nontargeting specificity, and poor blood brain barrier (BBB) permeability of the commercially available MR contrast agents. In this work, we developed a two-order targeted nanoprobe in which MR/optical imaging reporters, tumor vasculature targeted cyclic [RGDyK] peptides, and BBB-permeable Angiopep-2 peptides are labeled on the PAMAM-G5 dendrimer. This nanoprobe is supposed to first target the α(V)β(3) integrin on tumor vasculatures. Increased local concentration of nanoprobe facilitates the association between BBB-permeable peptides and the low-density lipoprotein receptor-related protein (LRP) receptors on the vascular endothelial cells, which further accelerates BBB transverse of the nanoprobe via LRP receptor-mediated endocytosis. The nanoprobes that have penetrated the BBB secondly target the brain tumor because both α(V)β(3) integrin and LRP receptor are highly expressed on the tumor cells. In vivo imaging studies demonstrated that this nanoprobe not only efficiently crossed intact BBB in normal mice, but also precisely delineated the boundary of the orthotropic U87MG human glioblastoma xenograft with high target to background signal ratio. Overall, this two-order targeted nanoprobe holds the promise to noninvasively visualize brain tumors with uncompromised BBB and provides the possibility for real-time optical-image-guided brain tumor resection during surgery.

Micelle‐Based Brain‐Targeted Drug Delivery Enabled by a Nicotine Acetylcholine Receptor Ligand

The blood–brain barrier (BBB) is the key challenge in the development of drugs for diseases of the central nervous system (CNS). The BBB prevents drugs or drug delivery systems from reaching the site of disease because of tight junctions and lack of fenestration. To circumvent this problem, the receptors that are highly expressed on the capillary endothelium of the brain, such as nicotine acetylcholine receptors (nAChRs), have been exploited to facilitate BBB crossing and intracranial transport of drug delivery systems. nAChRs are ligand-gated ion channels that are expressed mainly at the neuromuscular junction of the CNS, including the brain capillary endothelial cells. The extensive expression of nAChRs in the brain and susceptibility to the inhibition by peptide neurotoxins and neurotropic viral proteins endow them with the ability to mediate peptidebased transvascular delivery of various therapeutic agents to the brain. Herein, we report the design of a 16-residue peptide, derived from the loop II region of the snake neurotoxin candoxin, that binds to nAChRs with high affinity. This peptide, termed CDX, enabled drug delivery to the brain when conjugated to paclitaxel-loaded micelles. As a result, tumor growth in intracranial glioblastoma bearing mice was inhibited and their survival was prolonged. Snake neurotoxins are members of the “three-finger toxin” superfamily characterized by three adjacent loops arranged in a flat, leaflike structure. These toxins are known to bind through the second loop to nAChRs with high affinity and selectivity. Candoxin from the Malayan krait Bungarus candidus consists of a single polypeptide chain of 66 amino acid residues with five disulfide bridges, and antagonizes a7 neuronal nAChRs in nanomolar concentrations with poor reversibility. As was shown previously by western blot analysis, and confirmed by using immunocytochemical staining (Figure S8 in the Supporting Information), the a7 neuronal nAChR is richly expressed in primary brain capillary endothelial cells, and is thus ideally suited for candoxin-mediated, brain-targeted drug delivery. For this study, we designed and evaluated three short peptides derived from the loop II region of candoxin, FKESWREARGTRIERG (CDX), SWREARGTRI (Pocket_CDX), and disulfide bridged CFKESWREARGTRIERGC (Cyclo_CDX). To investigate whether or not the candoxin-derived peptides are capable of interacting with rat neuronal nAChRs, we performed a competitive binding assay where different concentrations of peptide competed for receptor binding with radiolabeled I-a-bungarotoxin, which is a potent antagonist of a7 neuronal nAChRs. All three peptides functioned as competitive antagonists of neuronal nAChRs in a dose-dependent manner (Figure S2). CDX displayed a Ki value of 0.187 mm, which is approximately 20– 40 times lower than those of Pocket_CDX and Cyclo_CDX (Table 1). Not surprisingly, CDX is substantially less potent than candoxin in nAChRs binding. The difference in potency is likely attributable, at least in part, to a loss of entropy for CDX, as it is unstructured in aqueous solution, as indicated by circular dichroism spectroscopic analysis (Figure S3).

Targeted gene delivery to glioblastoma using a C-end rule RGERPPR peptide-functionalised polyethylenimine complex

Safe and efficient systems capable of specifically targeting brain tumour cells represent a promising approach for the treatment glioblastoma multiforme. Neuropilin-1 (NRP-1) is over-expressed in U87 glioma cells. In the current study, the tumour specific peptide RGERPPR, which binds specifically to NRP-1, was used as a targeting ligand in a gene delivery strategy for glioblastoma. The RGERPPR peptide was coupled to branched polyethylenimine (PEI, 25kDa) using heterobifunctional Mal-PEG-NHS, resulting in a novel gene delivery polymer. Polymer/plasmid DNA (pDNA) complexes were formed and their sizes and zeta potentials were measured. Compared with the unmodified mPEG-PEI/pDNA complexes, the RGERPPR-PEG-PEI/pDNA complex led to a significant enhancement in intracellular gene uptake and tumour spheroid penetration. Furthermore, the RGERPPR-PEG-PEI/pDNA complex facilitated enhanced transfection efficiency levels, as well as a reduction in cytotoxicity when tested in U87 glioma cells in vitro. Most significantly of all, when complexes formed with pDsRED-N1 were injected into the tail vein of intracranial U87 tumour-bearing nude mice, the RGERPPR-PEG-PEI complexes led to improved levels of red fluorescence protein expression in the brain tissue. Taken together, the results show that RGERPPR-PEG-PEI could be used as a safe and efficient gene delivery vehicle with potential applications in glioblastoma gene delivery.

D-peptide inhibitors of the p53–MDM2 interaction for targeted molecular therapy of malignant neoplasms

The oncoproteins MDM2 and MDMX negatively regulate the activity and stability of the tumor suppressor protein p53, conferring tumor development and survival. Antagonists targeting the p53-binding domains of MDM2 and MDMX kill tumor cells both in vitro and in vivo by reactivating the p53 pathway, promising a class of antitumor agents for cancer therapy. Aided by native chemical ligation and mirror image phage display, we recently identified a D-peptide inhibitor of the p53-MDM2 interaction termed DPMI-α (TNWYANLEKLLR) that competes with p53 for MDM2 binding at an affinity of 219 nM. Increased selection stringency resulted in a distinct D-peptide inhibitor termed DPMI-γ (DWWPLAFEALLR) that binds MDM2 at an affinity of 53 nM. Structural studies coupled with mutational analysis verified the mode of action of these D-peptides as MDM2-dependent p53 activators. Despite being resistant to proteolysis, both DPMI-α and DPMI-γ failed to actively traverse the cell membrane and, when conjugated to a cationic cell-penetrating peptide, were indiscriminately cytotoxic independently of p53 status. When encapsulated in liposomes decorated with an integrin-targeting cyclic-RGD peptide, however, DPMI-α exerted potent p53-dependent growth inhibitory activity against human glioblastoma in cell cultures and nude mouse xenograft models. Our findings validate D-peptide antagonists of MDM2 as a class of p53 activators for targeted molecular therapy of malignant neoplasms harboring WT p53 and elevated levels of MDM2.

Functional interaction of human neutrophil peptide-1 with the cell wall precursor lipid II

Defensins constitute a major class of cationic antimicrobial peptides in mammals and vertebrates, acting as effectors of innate immunity against infectious microorganisms. It is generally accepted that defensins are bactericidal by disrupting the anionic microbial membrane. Here, we provide evidence that membrane activity of human α‐defensins does not correlate with antibacterial killing. We further show that the α‐defensin human neutrophil peptide‐1 (HNP1) binds to the cell wall precursor lipid II and that reduction of lipid II levels in the bacterial membrane significantly reduces bacterial killing. The interaction between defensins and lipid II suggests the inhibition of cell wall synthesis as a novel antibacterial mechanism of this important class of host defense peptides.

Toward Understanding the Cationicity of Defensins ARG AND LYS VERSUS THEIR NONCODED ANALOGS

Human defensins are a family of small antimicrobial proteins found predominantly in leukocytes and epithelial cells that play important roles in the innate and adaptive immune defense against microbial infection. The most distinct molecular feature of defensins is cationicity, manifested by abundant Arg and/or Lys residues in their sequences. Sequence analysis indicates that Arg is strongly selected over Lys in α-defensins but not in β-defensins. To understand this Arg/Lys disparity in defensins, we chemically synthesized human α-defensin 1 (HNP1) and several HNP1 analogs where three Arg residues were replaced by each of the following six α-amino acids: Lys, ornithine (Orn), diaminobutyric acid (Dab), diaminopropionic acid (Dap), N,N-dimethyl-Lys (diMeLys), and homo-Arg (homoArg). In addition, we prepared human β-defensin 1 (hBD1) and Lys→ArghBD1 in which all four Lys residues were substituted for Arg. Bactericidal activity assays revealed the following. 1) Arg-containing HNP1 and Lys→ArghBD1 are functionally better than Lys-HNP1 and hBD1, respectively; the difference between Arg and Lys is more evident in the α-defensin than in the β-defensin and is more evident at low salt concentrations than at high salt concentrations. 2) For HNP1, the Arg/Lys disparity is much more pronounced with Staphylococcus aureus than with Escherichia coli, and the Arg-rich HNP1 kills bacteria faster than its Lys-rich analog. 3) Arg and Lys appear to have optimal chain lengths for bacterial killing as shortening Lys or lengthening Arg in HNP1 invariably becomes functionally deleterious. Our findings provide insights into the Arg/Lys disparity in defensins, and shed light on the cationicity of defensins with respect to their antimicrobial activity and specificity.

LyP-1-conjugated nanoparticles for targeting drug delivery to lymphatic metastatic tumors

Active tumor targeting by biodegradable nanoparticles has been widely studied for cancer diagnosis and therapy. However, target-specific nanoparticles for drug delivery to lymphatic metastases have not been reported yet due to the lack of specific markers in the tumor lymphatics. Recently, peptide LyP-1 has been recognized for its specific home to tumors and their lymphatics. In this study, we tested the possibility of LyP-1 serving as a target-specific peptide of PEG-PLGA nanoparticles to tumor lymph metastases. LyP-1 was synthesized by using Boc-protected amino acids. The copolymers of maleimide-PEG-PLGA were formed by the conjugation of maleimide-PEG-NH(2) to PLGA-COOH, which were applied to prepare pegylated nanoparticles with mPEG-PLGA by means of double emulsion/solvent evaporation technique. LyP-1 with sulfhydryl group was conjugated to the maleimide function located at the distal end of PEG surrounding the nanoparticle surface. LyP-1-conjugated PEG-PLGA nanoparticle (LyP-1-NPs) had a round and regular shape with a diameter around 90 nm. In vitro, cellular uptake of LyP-1-NPs was about four times of that of PEG-PLGA nanoparticles without LyP-1 (NPs). In vivo, the uptake of LyP-1-NPs in metastasis lymph nodes was about eight times of that of NPs. This study indicates that LyP-1-NP is a promising carrier for target-specific drug delivery to lymphatic metastatic tumors.

LyP-1-conjugated PEGylated liposomes: a carrier system for targeted therapy of lymphatic metastatic tumor.

The application of liposomes in targeted therapy of lymphatic metastatic tumors has been hampered by the low uptake rate of liposome by metastatic lymph nodes. In this report, LyP-1, a peptide that can specifically bind tumor cells, tumor lymphatics and tumor-associated macrophages, was conjugated to liposomes for targeting and treating lymphatic metastatic tumors. Firstly, LyP-1-conjugated PEGylated liposomes loaded with fluorescein or doxorubicin (DOX) were prepared and showed satisfactory vesicle size and size distribution. The in vitro cellular uptake and in vivo near-infrared fluorescence imaging results showed that LyP-1 modification increased liposome uptake by tumor cells and metastatic lymph nodes, but did not increase uptake by normal lymph nodes. The immunofluorescence analysis evidenced that LyP-1-conjugated liposomes were distributed adjacent to tumor lymphatics and tumor-associated macrophages in metastatic lymph nodes. The pharmacodynamic study suggested that compared with unmodified liposomes, LyP-1-conjugated DOX-loaded liposomes exhibited enhanced inhibition effect on tumor cells in vitro and lymphatic metastatic tumors in vivo. Pathological examination showed that liposomal DOX caused reduced tissue damage to injection site compared with DOX solution. In summary, LyP-1-conjugated PEGylated liposomes could be targeted to metastatic lymph nodes based on their specific binding to tumor cells, tumor lymphatics and tumor-associated macrophages. They are a safe and effective drug delivery system of antineoplastic agents for targeted therapy of lymphatic metastatic tumors.

Systematic mutational analysis of peptide inhibition of the p53-MDM2/MDMX interactions.

Inhibition of the interaction between the tumor suppressor protein p53 and its negative regulators MDM2 and MDMX is of great interest in cancer biology and drug design. We previously reported a potent duodecimal peptide inhibitor, termed PMI (TSFAEYWNLLSP), of the p53-MDM2 and -MDMX interactions. PMI competes with p53 for MDM2 and MDMX binding at an affinity roughly 2 orders of magnitude higher than that of (17-28)p53 (ETFSDLWKLLPE) of the same length; both peptides adopt nearly identical alpha-helical conformations in the complexes, where the three highlighted hydrophobic residues Phe, Trp, and Leu dominate PMI or (17-28)p53 binding to MDM2 and MDMX. To elucidate the molecular determinants for PMI activity and specificity, we performed a systematic Ala scanning mutational analysis of PMI and (17-28)p53. The binding affinities for MDM2 and MDMX of a total of 35 peptides including 10 truncation analogs were quantified, affording a complete dissection of energetic contributions of individual residues of PMI and (17-28)p53 to MDM2 and MDMX association. Importantly, the N8A mutation turned PMI into the most potent dual-specific antagonist of MDM2 and MDMX reported to date, registering respective K(d) values of 490 pM and 2.4 nM. The co-crystal structure of N8A-PMI-(25-109)MDM2 was determined at 1.95 A, affirming that high-affinity peptide binding to MDM2/MDMX necessitates, in addition to optimized intermolecular interactions, enhanced helix stability or propensity contributed by non-contact residues. The powerful empirical binding data and crystal structures present a unique opportunity for computational studies of peptide inhibition of the p53-MDM2/MDMX interactions.