Ayelet David

E-selectin binding peptide-polymer-drug conjugates and their selective cytotoxicity against vascular endothelial cells.

The hypothesis that E-selectin on activated endothelial cells could be exploited to selectively target drug delivery systems to tumor vasculature was investigated. HPMA copolymer-doxorubicin (DOX) conjugates displaying the high affinity E-selectin binding peptide (Esbp, primary sequence DITWDQLWDLMK) as targeting ligand were synthesized and tested for their cytotoxicity and intracellular fate in human immortalized vascular endothelial cells (IVECs). The targeted copolymers displaying multiple copies of Esbp are bound to surface-associated E-selectin with affinity at the low nano-molar range, three orders of magnitude stronger than the free Esbp. In addition, the binding affinity of the HPMA-Esbp copolymers to E-selectin expressing IVECs was found to be 10-fold superior relative to non-targeted copolymers. Once bound, E-selectin facilitated rapid internalization and lysosomal trafficking of the copolymers. This lysosomotropism of HPMA-Esbp-bound DOX copolymers was then correlated with a 150-fold higher cytotoxicity relative to non-targeted HPMA-DOX conjugates. These findings strongly support the emerging role of E-selectin as a viable target for controlled drug delivery in cancer therapy.

Hyaluronan Oligomers-HPMA Copolymer Conjugates for Targeting Paclitaxel to CD44-Overexpressing Ovarian Carcinoma

PurposeTo evaluate the effect of the size of low molecular weight hyaluronan (LMW-HA) oligomers on the targeting ability of the HA-containing copolymers to the CD44-overexpressing cells for delivering Paclitaxel (PTX) to ovarian cancer.MethodsLMW-HA oligosaccharides of 4, 6, 8, 10, 12 and 14 sugar residues were attained by digestion of HMW-HA using hyaluronate lyase at different incubation times and then attached to FITC-labeled HPMA copolymer precursor. The binding and uptake of the HA-modified HPMA-copolymer into CD44-expressing cells was studied by flow cytometry and confocal microscopy. PTX was further attached to HPMA-copolymer precursor bearing HA oligosaccharide at the size of 34 monosaccharides, through an acid-sensitive hydrazone linker. The cytotoxicity of the polymer was tested using cell viability assay.ResultsPolymer conjugates bearing HA oligomers at the size of 10 oligosaccharides and above (HA10–14) bind actively and profoundly to CD44-overexpressing ovarian cancer cells (SK-OV-3) and internalize to the greatest extent relative to HA-polymer conjugates of 8 oligomers and below (HA4–8). The HA-modified HPMA-copolymer PTX conjugate (P-(HA)34-PTX) exhibited 50-times higher cytotoxicity towards CD44-overexpressing cells relative to the control, non-targeted, HPMA-copolymer PTX conjugate (P-PTX).ConclusionsP-(HA)34-PTX was significantly more toxic than the non-targeted P-PTX in cells expressing high levels of CD44

Multivalent Display of Quinic Acid Based Ligands for Targeting E-Selectin Expressing Cells

The site-specific expression of molecular markers on endothelial cells of blood vessels during inflammatory response and angiogenesis provides an opportunity to target drugs and imaging molecules to the vascular endothelium of diseased tissues. This paper describes an innovative strategy for selective delivery of polymer conjugates to E- and P-selectin expressing cells using a series of quinic acid (Qa) based non-carbohydrate analogues of the natural ligand sialyl Lewis(x) (sLe(x)) as targeting moieties. We demonstrate that such analogues antagonize the adhesion of sLe(x) expressing HL-60 cells to both E- and P-selectin. Significantly, the apparent avidity of polymer conjugates carrying multiple Qa copies has increased by 3 orders of magnitude relative to their monomeric forms. Furthermore, we found that the major mechanism of copolymer entry and delivery into E-selectin expressing cells is endocytosis. These selectin-targetable copolymers provide the foundation to support controlled delivery of anticancer drugs and imaging agents to tumor vasculature for therapeutic and diagnostic applications.

Peptide-directed HPMA copolymer-doxorubicin conjugates as targeted therapeutics for colorectal cancer.

Synthetic oligopeptides have emerged as a promising class of targeting ligands, providing a variety of choices for the construction of conjugates for desired ligand functionality. To explore the potential of short peptides as ligands for targeted delivery of macromolecular therapeutics for colorectal cancer (CRC), fluorescently labelled HPMA copolymers—bearing either G3-C12 or GE11 for targeting galectin-3 and epidermal growth factor receptor (EGFR), respectively—were synthesised and the mechanisms of their internalisation and subcellular fate in CRC cells were studied. The targetability of the G3-C12 bearing copolymers towards galectin-3 was further compared to that of galactose-containing copolymers. The resulting G3-C12-bearing conjugate actively and selectively targets CRC tumour cells over-expressing galectin-3 and exhibits superior targetability to galectin-3 when compared to the galactose-bearing copolymer. GE11 copolymer conjugate binds specifically and efficiently to EGFR over-expressing cells, thus mediating internalisation to a significantly higher extent relative the copolymer conjugated to a scrambled sequence peptide. We further incorporated doxorubicin (DOX) into GE11 bearing copolymer via an acid-labile hydrazone bond. The GE11-DOX copolymer conjugate demonstrated higher cytotoxicity toward EGFR over-expressing cells relative to the control non-targeted DOX conjugate. Altogether, our results show a proof of principle for the selective delivery of DOX to the target CRC cells.

Mannosylated polyion complexes for in vivo gene delivery into CD11c(+) dendritic cells.

Dendritic cells (DCs) possess unique abilities in initiating primary immune responses and thus represent prime targets for DNA-based vaccinations. Here, we describe the design and synthesis of mannosylated polyion complexes (PICs) composed of cationic polyethylenimine (PEI) and hydrophilic polyethylene glycol (PEG) segments, and bearing mono- and trivalent mannose as a ligand for targeting mannose receptor (MR/CD206)-positive DCs. Amino-terminated mannose (Man)-containing ligands in mono- and trivalent presentations (Man- and Man3-, respectively) were prepared and conjugated to PEG via an N-hydroxysuccinimide (NHS)-activated terminal. Thiolated PEI was conjugated to the mannosylated PEG via the maleimide (MAL)-activated terminal. The resulting positively charged diblock copolymers bearing mannoses (Man-PEG-b-PEI and Man3-PEG-b-PEI) were self-assembled with DNA to form PICs with lower surface charge than did their PEI building block and mean hydrodynamic diameters in the range of 100-450 nm, depending on the N/P ratio. Man3-PEG-b-PEI demonstrated a 3-4-fold greater transfection efficiency in MR-positive dendritic cell lines (THP-1, DC2.4), relative to Man-PEG-b-PEI, exhibited low cytotoxicity when compared with PEI, and showed low transfection efficiency in nondendritic HeLa cells. In preliminary in vivo experiments, Man-PEG-b-PEI/DNA and Man3-PEG-b-PEI/DNA demonstrated 2-3-fold higher gene delivery efficiency into CD11c(+) DCs collected from inguinal lymph nodes of C57/BL6 mice, when compared to PEI/DNA complexes, as shown by GFP expression measurements, 24 h post subcutaneous injection. The results indicate that the mannosylated PICs are a safe and effective gene delivery system, showing in vivo specificity toward CD11c(+) DCs.

Peptide ligand-modified nanomedicines for targeting cells at the tumor microenvironment

Abstract Since their initial discovery more than 30 years ago, tumor‐homing peptides have become an increasingly useful tool for targeted delivery of therapeutic and diagnostic agents into tumors. Today, it is well accepted that cells at the tumor microenvironment (TME) contribute in many ways to cancer development and progression. Tumor‐homing peptide‐decorated nanomedicines can interact specifically with surface receptors expressed on cells in the TME, improve cellular uptake of nanomedicines by target cells, and impair tumor growth and progression. Moreover, peptide ligand‐modified nanomedicines can potentially accumulate in the target tissue at higher concentrations than would small conjugates, thus increasing overall target tissue exposure to the therapeutic agent, enhance therapeutic efficacy and reduce side effects. This review describes the most studied peptide ligands aimed at targeting cells in the TME, discusses major obstacles and principles in the design of ligands for drug targeting and provides an overview of homing peptides in ligand‐targeted nanomedicines that are currently in development for cancer therapy and diagnosis. Graphical abstract No caption available.

Assessing the therapeutic efficacy of VEGFR-1-targeted polymer drug conjugates in mouse tumor models.

Polymer-drug conjugates that can actively target the tumor vasculature have emerged as an attractive technology for improving the therapeutic efficacy of cytotoxic drugs. We have recently provided, for the first time, in vivo evidence showing the significant advantage of the E-selectin-targeted N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer-doxorubicin conjugate, P-(Esbp)-DOX, in inhibiting primary tumor growth and preventing the formation and development of cancer metastases. Here, we describe the design of a vascular endothelial growth factor receptor (VEGFR)-1-targeted HPMA copolymer-DOX conjugate (P-(F56)-DOX) that can actively and simultaneously target different cell types in the tumor microenvironment, such as endothelial cells (ECs), bone marrow-derived cells and many human cancer cells of diverse tumor origin. The VEGFR-1-targeted copolymer was tested for its binding, internalization and in vitro cytotoxicity in ECs (bEnd.3 and cEND cells) and cancer cells (B16-F10, 3LL and HT29). The in vivo anti-cancer activity of P-(F56)-DOX was then tested in two tumor-bearing mice (TBM) models (i.e., primary Lewis lung carcinoma (3LL) tumors and B16-F10 melanoma pulmonary metastases), relative to that of the E-selectin-targeted system (P-(Esbp)-DOX) that solely targets ECs. Our results indicate that the binding and internalization profiles of the VEGFR-1-targeted copolymer were superior towards ECs as compared to cancer cells and correlated well to the level of VEGFR-1 expression in cells. Accordingly, the VEGFR-1-targeted copolymer (P-(F56)-DOX) was more toxic towards bEnd.3 cells than to cancer cells, and exhibited significantly higher cytotoxicity than did the non-targeted control copolymer. P-(F56)-DOX inhibited 3LL tumor growth and significantly prolonged the survival of mice with B16-F10 pulmonary metastases. When compared to a system that actively targets only tumor vascular ECs, P-(F56)-DOX and P-(Esbp)-DOX exhibited comparable efficacy in slowing the growth of primary 3LL tumors and prolonging the survival of these mice. Still, P-(Esbp)-DOX had more pronounced anti-tumor activity in mice bearing B16-F10 lung metastases after a single intravenous injection, at an equivalent DOX dose. Overall, our results indicate that the VEGFR-1- and E-selectin-targeted drug delivery systems evaluated here show enhanced anti-cancer activity, and prolonged the survival of mice after a single intravenous injection. This is thus the first study comparing the anti-tumor activity of VEGFR-1- and E-selectin-targeted polymer drug conjugates in the same TBM models at an equivalent drug dose.

Complexation of Cell-Penetrating Peptide–Polymer Conjugates with Polyanions Controls Cells Uptake of HPMA Copolymers and Anti-tumor Activity

ABSTRACTPurposeCell penetrating peptides (CPPs) can mediate effective delivery of their associated drugs and drug carriers intracellularly, however their lack of cell specificity remains a major obstacle for their clinical development. We aimed at improving the cell specificity and therapeutic efficacy of HPMA copolymer-octaarginine (R8) conjugate (P-R8) in cells at the tumor micro-environment.MethodsTo avoid premature cell-penetration, the positively charged R8 moieties were masked via electrostatic complexation with various polyanionic molecules (heparin sulfate, hyaluronic acid, fucoidan and poly-glutamic acid). We followed the kinetics of the FITC-labeled P-R8 penetration into endothelial and cancer cells over-time after its complexation in vitro and further tested whether the in situ addition of a stronger polycation can trigger the release of P-R8 from the complexes to resume cell penetration activity. A murine model of B16-F10 lung metastasis was then used as an in vivo model for assessing the therapeutic efficacy of the P-R8, loaded with doxorubicin (P-R8-DOX), after its complexation with PGA.ResultsThe intracellular penetration of P-R8-FITC was reversibly inhibited by forming electrostatic interactions with counter polyanions, and can be restored either gradually over time by dissociation from the polyanions, or promptly following the addition of protamine sulfate. Mice injected with B16-F10 cells and treated with P-R8-DOX/PGA complexes, exhibited a significant prolonged survival times when compared with DOX-treated mice or relative to mice treated with either P-R8-DOX or P-DOX alone.ConclusionsThe gradual release of P-R8 from P-R8-DOX/PGA may improve the therapeutic efficacy of water-soluble based nanomedicines for the treatment of solid lung tumors.

Intra-colonic administration of a polymer-bound NIRF probe for improved colorectal cancer detection during colonoscopy

There is increasing interest in the use of nanoparticle imaging probes for cancer diagnosis. However, various biological barriers limit the efficient delivery of nanoparticles to tumors following parenteral administration. We have investigated the applicability of a water-soluble polymeric imaging probe for improving the detection of gastrointestinal (GI) tumors after intra-luminal (colonic) administration. N-(2-hydroxypropyl)methacrylamide (HPMA) copolymers bearing either fluorescein-isothiocyanate (FITC) or near-infrared fluorescence (NIRF) dye (IR-783) were conjugated with EPPT1 peptide, derived from the CDR3 Vh region of a monoclonal antibody (ASM2) raised against human epithelial cancer cells, for targeting under-glycosylated mucin-1 (uMUC-1) expressed in neoplastic tissues. The targeted FITC-labeled copolymer, P-(EPPT1)-FITC, was investigated for its ability to bind human CRC cells and tissue specimens in vitro. The uMUC-1-targeted NIRF-labeled copolymer, P-(EPPT1)-IR783, was assessed for its ability to detect colonic lesions in vivo. P-(EPPT1)-FITC demonstrated superior binding to colorectal cancer (CRC) cells that over-express the uMUC-1 antigen and exhibited selectivity towards human CRC tissue specimens, as compared to adjacent normal tissues from the same patient. When applied intra-colonically, P-(EPPT1)-IR783 significantly accumulated in cancerous tissue, relative to the adjacent normal mucosa of HT29 and LS174T tumor-bearing mice, and demonstrated higher signal intensities in colonic tumors, as compared to the non-targeted P-(GG-OH)-IR783 probe (i.e., without EPPT1). We found that P-(GG-OH)-IR783 can also accumulate specifically at tumor sites. The cancer-specific uptake and retention of P-(GG-OH)-IR783 was not mediated by organic anion transporting peptides (OATPs). Our findings indicate that the polymer-bound NIRF probe can successfully detect solid tumors in the GI tract following intra-colonic administration, and could be used in conjunction with colonoscopic procedures to improve the sensitivity of colonoscopies for polyp detection.

Conjugates of HA2 with octaarginine-grafted HPMA copolymer offer effective siRNA delivery and gene silencing in cancer cells.

The key for successful gene silencing is to design a safe and efficient siRNA delivery system for the transfer of therapeutic nucleic acids into the target cells. Here, we describe the design of hydrophilic N-(2-hydroxypropyl)methacrylamide (HPMA) copolymer displaying multiple copies of octaarginine (R8) and its use in promoting the effective delivery of small interfering RNA (siRNA) molecules intracellularly. Fluorescein-5-isothiocyanate (FITC)-labeled HPMA copolymer-bound R8 (P-R8-FITC) was synthesized with increasing R8 molar ratios (4-9.5mol-%) to define the optimal R8 content that allowed the polymer to serve both as a siRNA-binding domain and as an intracellular transduction moiety mediating improved cellular delivery. A subunit of the influenza virus hemagglutinin (HA2), known for its ability to disrupt endosomal membranes, was further conjugated to P-R8-FITC copolymer to promote endosomal escape. Of the different P-(R8)-FITC conjugates considered, only that polymer containing the highest mol-% of R8 (P-(R8)9.5-FITC) was able to encapsulate siRNA molecules into nano-sized polyion complexes (PICs) presenting positive surface charge, low in vitro cytotoxicity, and high serum stability. P-(R8)9.5-FITC/cy5-siRNA complexes can efficiently deliver siRNA molecules into cells, while naked siRNA or siRNA encapsulated within polymers with lower R8mol-% were unable to transfect the same cells. Conjugation of HA2 fusogenic peptide to P-(R8)-FITC significantly decreased the oncogenic RAC1 mRNA levels in cancer cells. This indicates that P-(R8)-(HA2)-FITC can deliver siRNA into target cells, and that the siRNA can reach the perinuclear region where it interacts with the RNA-induced silencing complex.