Leucine-aspartic acid-valine sequence as targeting ligand & drug carrier for doxorubicin delivery to melanoma cells

Zhong, Sha

01 January 2009

The goal of cancer chemotherapy is to develop effective, safe, and well-tolerated medications. The over-expression of certain receptors on cancer cell membrane provides a basis for active targeting by not only specific interaction between drug delivery system and cells, but also facilitated cellular uptake via receptor-mediated endocytosis. In this study, LDV oligomers up to six LDV repeating units were synthesized via solid phase peptide synthesis method, and evaluated as drug carrier as well as targeting moiety to deliver doxorubicin (Dox) to human malignant melanoma cells (A375), which over-express integrin α 4 β 1 . Cells expressing different levels of integrin α 4 β 1 or modulated using integrin α 4 -specific siRNA knock-down technique were verified by western blot and PCR. Magnetic beads with tripeptides LDV, VDL, or LNV on the surface were used in the binding specificity studies. Results verified that LDV was the minimally required ligand sequence for the specific binding to integrin α 4 β 1 , of which the interaction depends on the amount of integrin and can be utilized for the design of targeted drug delivery. The studies on A375 cells uptake of FITC-labeled LDV oligomers examined the effects of EDTA, temperature, endocytosis inhibitor, and competitive ligand. Cellular uptake mechanism was revealed to be temperature-dependent, receptor-mediated endocytosis, involving the specific interaction between LDV and integrin α 4 β 1 . The internalization extent of LDV monomer was the highest and was also inhibited to the most by the addition of free LDV when compared to other LDV oligomers. Cytotoxicity profiles of Dox-conjugated LDV oligomers were obtained on wild-type A375, integrin α4 knock-down A375, and normal human epithelial keratinocytes (NHEK) using SRB assay. A significant decrease (3∼6 folds) in the cytotoxicity of oligo(LDV)-Dox on A375 cells were observed when the integrin α4 expression was knocked down by ∼50%. Cytotoxicity further decreased on NHEK, which has the lowest integrin α4 expression among three cell lines. In contrast to oligo(LDV)-Dox, free Dox was not able to differentiate between cancerous and normal cells. This result demonstrated the potential of oligo(LDV) as targeting ligand. However, increase of repeating LDV unit did not lead to any apparent trend in cytotoxicity capacity. To facilitate the intracellular Dox release, hydrazone bond (HYD) was introduced between LDV and Dox. In vitro Dox release profiles in pH 6.0, 7.4, and rat plasma proved the pH-sensitivity of LDV-HYD-Dox. Cytotoxicity studies showed an increased cytotoxic effect of LDV-HYD-Dox when compared with LDV-Dox on wild-type A375 (2.5 times), knock-down A375 (1.5 times); while no significant difference in cytotoxicity on NHEK was observed. In vivo animal study supported the in vitro findings on LDV-HYD-Dox, which showed a significant inhibition of tumor growth and longest mice life span when compared to free Dox, poly(L,D,V)-Dox, and LDV-Dox, with averagely only ¼ of the tumor size and almost twice the life span of that from the free Dox group. In conclusion, based on the concept of specific interaction between LDV and integrin α 4 β 1 , oligo(LDV)-Dox targeted drug delivery system was developed and proved to be effective in the delivery of Dox to melanoma cells.

Pharmacy sciences

Health and environmental sciences

Pure sciences

Doxorubicin

Leucine-aspartic acid-valine

Melanoma

Oligo (LDV)

Poly (L

D

V)

Targeted delivery

Pharmacy and Pharmaceutical Sciences

DNA Nanoparticles for Non-viral Gene Therapy: Mechanistic Studies and Targeting

Sun, Wenchao

26 June 2012

No description available.

Biochemistry

Biomedical Research

Nanotechnology

Polymers

DNA nanoparticles

non-viral gene therapy

polylysine

reducible linkage

disulfide bond

extracellular mechanism

targeted delivery

non-covalent conjugation

TAT peptide

monovalent streptavidin

Poly(Propylene imine)-based polyplexes for non-viral, targeted delivery of nucleic acids into PSCA-positive tumor cells

Jugel, Willi

17 January 2024

Delivery of siRNAs for the treatment of tumors critically depends on the development of efficient nucleic acid carrier systems. The complexation of dendritic polymers (dendrimers) results in nanoparticles, called dendriplexes, that protect siRNA from degradation and mediate non-specific cellular uptake of siRNA. However, large siRNA doses are required for in vivo use due to accumulation of the nanoparticles in sinks such as the lung, liver, and spleen. This suggests the exploration of targeted nanoparticles for enhancing tumor cell specificity and achieving higher siRNA levels in tumors. In this work, we report on the targeted delivery of a therapeutic siRNA specific for BIRC5/Survivin in vitro and in vivo to tumor cells expressing the surface marker prostate stem cell antigen (PSCA). For this, polyplexes consisting of single-chain antibody fragments specific for PSCA conjugated to siRNA/maltose-modified poly(propylene imine) dendriplexes were used. These polyplexes were endocytosed by PSCA-positive 293TPSCA/ffLuc and PC3PSCA cells and caused knockdown of reporter gene firefly luciferase and Survivin expression, respectively. In a therapeutic study in PC3PSCA xenograft-bearing mice, significant anti-tumor effects were observed upon systemic administration of the targeted polyplexes. This indicates superior anti-tumor efficacy when employing targeted delivery of Survivin-specific siRNA, based on the additive effects of siRNA-mediated Survivin knockdown in combination with scFv-mediated PSCA inhibition. Among non-viral vectors, cationic polymers, such as poly(propylene imine) (PPI), play also a prominent role in plasmid DNA delivery. However, limitations of polycationic polymer-based DNA delivery systems are (i) insufficient target specificity, (ii) unsatisfactory transgene expression, and (iii) undesired transfer of therapeutic DNA into non-target cells. We developed single-chain antibody fragment (scFv)-directed hybrid polyplexes for targeted gene therapy of prostate stem cell antigen (PSCA)-positive tumors. Besides mono-biotinylated PSCA-specific single-chain antibodies (scFv(AM1-P-BAP)) conjugated to neutravidin, the hybrid polyplexes comprise β cyclodextrin-modified PPI as well as biotin/maltose-modified PPI as carriers for minicircle DNAs encoding for Sleeping Beauty transposase and a transposon encoding the gene of interest. The PSCA-specific hybrid polyplexes efficiently delivered a GFP gene in PSCA-positive tumor cells, whereas control hybrid polyplexes showed low gene transfer efficiency. In an experimental gene therapy approach, targeted transposition of a codon-optimized p53 into p53 deficient HCT116p53-/-/PSCA cells demonstrated decreased clonogenic survival when compared to mock controls. Noteworthily, p53 transposition in PTEN-deficient H4PSCA glioma cells caused nearly complete loss of clonogenic survival. These results demonstrate the feasibility of combining tumor-targeting hybrid polyplexes and Sleeping Beauty gene transposition, which, due to the modular design, can be extended to other target genes and tumor entities.

info:eu-repo/classification/ddc/610

ddc:610

Polymeric micelles as versatile carriers for drugs and nucleic acids

El Sabahy, Mahmoud

08 1900

Le cancer est la principale cause de mortalité au Canada. Les taxanes (e.g. le paclitaxel et le docétaxel (DCTX)) constituent des remèdes efficaces contre une série de tumeurs solides telles que les cancers du sein, du poumon et de l’ovaire. Par ailleurs, des acides nucléiques (e.g. les oligonucléotides antisens (AON) ou les petits ARN interférents (siRNAs)), capables de supprimer sélectivement certains oncogènes impliqués dans la carcinogénèse, sont actuellement étudiés pour traiter une large gamme de cancers. Bien que l’activité des taxanes et des acides nucléiques soit bien établie sur des modèles humains et/ou animaux, plusieurs aspects physico-chimiques et cliniques restent encore à améliorer. Leur solubilité limitée (pour les taxanes), leur dégradation rapide dans le sang (pour les acides nucléiques), leur élimination précoce, leur absence de sélectivité et leur toxicité envers les tissus sains sont les principaux facteurs limitant leur efficacité. C’est pourquoi de nombreux efforts ont porté sur l’élaboration de systèmes de vectorisation ciblés à base de polymères, dans le but de surmonter les problèmes associés aux thérapies actuelles. Dans cette thèse, deux types de micelles polymères ont été développés pour la vectorisation de DCTX et d’acides nucléiques. D’une part, des micelles de poly(oxyde d’éthylène)-bloc-poly(oxyde de butylène/styrène) ont été étudiées pour la première fois pour solubiliser le DCTX et le protéger de l’hydrolyse. Ces polymères se sont révélés moins toxiques que le surfactant utilisé commercialement pour solubiliser le DCTX (i.e. polysorbate 80) et ont permis une libération prolongée du principe actif. D’autre part, deux systèmes différents de micelles polyioniques (PICM) ont été mis au point pour la vectorisation d’acides nucléiques. De nouveaux conjugués de poly(éthylène glycol) (PEG)-oligonucléotide ont été proposés pour la protection et la libération contrôlée d’AON. Lorsque ces conjugués ont été formulés avec des dendrimères de poly(amidoamine) (PAMAM), des complexes de taille homogène ont été obtenus. Ces PICM ont permis de prolonger la libération de l’AON et de le protéger efficacement contre la dégradation enzymatique. De plus, des polymères de poly(oxyde d’éthylène)-bloc-poly(méthacrylate de propyle-co-acide méthacrylique) ont été incorporés afin de conférer des propriétés acido-sensibles aux PICM. Dans ces micelles, formées de ce dernier polymère formulé avec le dendrimère PAMAM, des oligonucléotides (AON et siRNA) ciblant l’oncogène Bcl-2 ont été encapsulés. L’internalisation cellulaire fut assurée par un fragment d’anticorps monoclonal (Fab’) situé à l’extrémité de la couronne de PEG. Après l’internalisation cellulaire et la protonation des unités d’acide méthacrylique sous l’effet de l’acidification des endosomes, les micelles se sont affranchies de leur couronne. Elles ont ainsi exposé leur cœur composé d’acide nucléique et de dendrimère PAMAM, qui possède une charge positive et des propriétés endosomolytiques. En effet, ces PICM acido-sensibles ciblées ont permis d’augmenter la biodisponibilité des acides nucléiques vectorisés et se sont avérées plus efficaces pour silencer l’oncoprotéine Bcl-2 que les micelles non ciblées ou que le dendrimère de PAMAM commercial seul. Finalement, les nanovecteurs polymères présentés dans cette thèse se révèlent être des systèmes prometteurs pour la vectorisation des anticancéreux et des acides nucléiques. / Cancer is considered as the leading cause of premature death in Canada. Taxanes (e.g. paclitaxel and docetaxel (DCTX)) are effective against a range of solid tumors including breast, lung, and ovarian malignancies. In addition, nucleic acids (e.g. antisense oligonucleotides (AON) and short interfering RNA (siRNA)) which are capable of selectively suppressing oncogenes involved in carcinogenesis are currently being investigated for the treatment of a wide variety of cancers. Although the activity of taxanes and nucleic acid drugs is well-established in human and/or animal models, several physicochemical and clinical issues still need to be addressed. Low aqueous solubility (i.e. taxanes), rapid degradation in the blood (i.e. nucleic acids), fast clearance, non-selectivity and toxicity to normal tissues are limiting factors to their effectiveness. Hence, many efforts have been focused on developing targeted polymeric delivery systems to overcome the problems associated with the current therapies. In this thesis, two types of polymeric micelles have been developed for the delivery of DCTX and nucleic acids. On the one hand, poly(ethylene oxide)-block-poly(butylene oxide/styrene oxide) micelles were tested for the first time to solubilize and protect DCTX from hydrolytic degradation. The polymers showed less toxicity than the surfactant used commercially to dissolve DCTX (i.e. polysorbate 80) and released the drug in a sustained fashion. On the other hand, two different systems of polyion complex micelles (PICM) were developed for the sustained release and intracellular delivery of nucleic acids. Novel poly(ethylene glycol) (PEG)-oligonucleotide conjugates were assessed to protect AON against degradation and release them in a sustained manner. When these conjugates were mixed with poly(amidoamine) (PAMAM) dendrimers, monodisperse PICM were formed. These PICM further slowed down AON release and significantly protected it against enzymatic degradation. In addition, the incorporation of poly(ethylene oxide)-block-poly(propyl methacrylate-co-methacrylic acid) was exploited to impart pH-sensitivity to PAMAM-based PICM. This system was composed of the previous copolymer mixed with PAMAM dendrimer. Such PICM were loaded with AON or siRNA targeting the Bcl-2 oncogene. Micelles uptake by the cancer cells was mediated by a monoclonal antibody fragment (i.e. Fab') positioned at the extremity of the PEG corona. Upon cellular uptake and protonation of the methacrylic acid units in the acidic endosomal environment, the micelles lost their corona, thereby exposing their positively-charged endosomolytic PAMAM/nucleic acid core. The targeted, pH-sensitive PICM were found to increase the intracellular bioavailability of the entrapped nucleic acids and knock down the Bcl-2 oncoprotein more than either non-targeted micelles or commercial PAMAM dendrimers. The polymeric nanocarriers reported in this thesis appear to be promising vehicles for the delivery of anticancer drugs and nucleic acids.

Micelles polymères

Micelles polyioniques

Docétaxel

Oligonucléotide antisens

SiRNA

Dendrimères de poly(amidoamine)

Vectorisation de médicament

Vectorisation d’acides nucléiques

Sensibilité au pH

Ciblage

Polymeric micelles

Polyion complex micelles

Docetaxel

Antisense oligonucleotide

SiRNA

Poly(amidoamine) dendrimers

Drug delivery

Nucleic acid delivery

PH-sensitivity

Targeted delivery

Polymeric micelles as versatile carriers for drugs and nucleic acids

El Sabahy, Mahmoud

08 1900

No description available.

Micelles polymères

Micelles polyioniques

Docétaxel

Oligonucléotide antisens

SiRNA

Dendrimères de poly(amidoamine)

Vectorisation de médicament

Vectorisation d’acides nucléiques

Sensibilité au pH

Ciblage

Polymeric micelles

Polyion complex micelles

Docetaxel

Antisense oligonucleotide

SiRNA

Poly(amidoamine) dendrimers

Drug delivery

Nucleic acid delivery

PH-sensitivity

Targeted delivery