siRNA-Mediated Knock-Down of P-Glycoprotein Expression Reveals Distinct Cellular Disposition of Anticancer Tyrosine Kinases Inhibitors.

Studies on the cellular disposition of targeted anticancer tyrosine kinases inhibitors (TKIs) have mostly focused on imatinib while the functional importance of P-glycoprotein (Pgp) the gene product of MDR1 remains controversial for more recent TKIs. By using RNA interference-mediated knockdown of MDR1, we have investigated and compared the specific functional consequence of Pgp on the cellular disposition of the major clinically in use TKIs imatinib, dasatinib, nilotinib, sunitinib and sorafenib. siRNA-mediated knockdown in K562/Dox cell lines provides a unique opportunity to dissect the specific contribution of Pgp to TKIs intracellular disposition. In these conditions, abrogating specifically Pgp-mediated efflux in vitro revealed the remarkable and statistically significant cellular accumulation of imatinib (difference in cellular levels between Pgp-expressing and silenced cells, at high and low incubation concentration, respectively: 6.1 and 6.6), dasatinib (4.9 and 5.6), sunitinib (3.7 and 7.3) and sorafenib (1.2 and 1.4), confirming that these TKIs are all substrates of Pgp. By contrast, no statistically significant difference in cellular disposition of nilotinib was observed as a result of MDR1 expression silencing (differences: 1.1 and 1.5) indicating that differential expression and/or function of Pgp is unlikely to affect nilotinib cellular disposition. This study enables for the first time a direct estimation of the specific contribution of one transporter among the various efflux and influx carriers involved in the cellular trafficking of these major TKIs in vitro. Knowledge on the distinct functional consequence of Pgp expression for these various TKIs cellular distribution is necessary to better appreciate the efficacy, toxicity, and potential drug-drug interactions of TKIs with other classes of therapeutic agents, at the systemic, tissular and cellular levels.

Platinum (II) and palladium (II) complexes with (N,N') and (C,N,N') ligands derived from pyrazole as anticancer and antimalarial agents: synthesis, characterization and in vitro activities

The study of the reactivity of three 1-(2-dimethylaminoethyl)-1H-pyrazole derivatives of general formula [1-(CH2)2NMe2}-3,5-R2-pzol] {where pzol represents pyrazole and Rdouble bond; length as m-dashH (1a), Me (1b) or Ph (1c)} with [MCl2(DMSO)2] (Mdouble bond; length as m-dashPt or Pd) under different experimental conditions allowed us to isolate and characterize cis-[M{κ2-N,N′-{[1-(CH2)2NMe2}-3,5-R2-pzol])}Cl2] {MMdouble bond; length as m-dashPtPt (2a-2c) or Pd (3a-3c)} and two cyclometallated complexes [M{κ3-C,N,N′-{[1-(CH2)2NMe2}-3-(C5H4)-5-Ph-pzol])}Cl] {Mdouble bond; length as m-dashPt(II) (4c) or Pd(II) (5c)}. Compounds 4c and 5c arise from the orthometallation of the 3-phenyl ring of ligand 1c. Complex 2a has been further characterized by X-ray crystallography. Ligands and complexes were evaluated for their in vitro antimalarial against Plasmodium falciparum and cytotoxic activities against lung (A549) and breast (MDA MB231 and MCF7) cancer cellular lines. Complexes 2a-2c and 5c exhibited only moderate antimalarial activities against two P. falciparum strains (3D7 and W2). Interestingly, cytotoxicity assays revealed that the platinacycle 4c exhibits a higher toxicity than cisplatin in the three human cell lines and that the complex 2a presents a remarkable cytotoxicity and selectivity in lung (IC50 = 3 μM) versus breast cancer cell lines (IC50 > 20 μM). Thus, complexes 2c and 4c appear to be promising leads, creating a novel family of anticancer agents. Electrophoretic DNA migration studies in presence of the synthesized compounds have been performed, in order to get further insights into their mechanism of action.

Lethal weapons : novel approaches for receptor-targeted cancer cell elimination

The currently used forms of cancer therapy are associated with drug resistance and toxicity to healthy tissues. Thus, more efficient methods are needed for cancer-specific induction of growth arrest and programmed cell death, also known as apoptosis. Therapeutic forms of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) are investigated in clinical trials due to the capability of TRAIL to trigger apoptosis specifically in cancer cells by activation of cell surface death receptors. Many tumors, however, have acquired resistance to TRAIL-induced apoptosis and sensitizing drugs for combinatorial treatments are, therefore, in high demand. This study demonstrates that lignans, natural polyphenols enriched in seeds and cereal, have a remarkable sensitizing effect on TRAIL-induced cell death at non-toxic lignan concentrations. In TRAIL-resistant and androgen-dependent prostate cancer cells we observe that lignans repress receptor tyrosine kinase (RTK) activity and downregulate cell survival signaling via the Akt pathway, which leads to increased TRAIL sensitivity. A structure-activity relationship analysis reveals that the γ-butyrolactone ring of the dibenzylbutyrolactone lignans is essential for the rapidly reversible TRAIL-sensitizing activity of these compounds. Furthermore, the lignan nortrachelogenin (NTG) is identified as the most efficient of the 27 tested lignans and norlignans in sensitization of androgen-deprived prostate cancer cells to TRAIL-induced apoptosis. While this combinatorial anticancer approach may leave normal cells unharmed, several efficient cancer drugs are too toxic, insoluble or unstable to be used in systemic therapy. To enable use of such drugs and to protect normal cells from cytotoxic effects, cancer-targeted drug delivery vehicles of nanometer scale have recently been generated. The newly developed nanoparticle system that we tested in vitro for cancer cell targeting combines the efficient drug-loading capacity of mesoporous silica to the versatile particle surface functionalization of hyperbranched poly(ethylene imine), PEI. The mesoporous hybrid silica nanoparticles (MSNs) were functionalized with folic acid to promote targeted internalization by folate receptor overexpressing cancer cells. The presented results demonstrate that the developed carrier system can be employed in vitro for cancer selective delivery of adsorbed or covalently conjugated molecules and furthermore, for selective induction of apoptotic cell death in folate receptor expressing cancer cells. The tested carrier system displays potential for simultaneous delivery of several anticancer agents specifically to cancer cells also in vivo.

Antitumor activity of an epithelial cell adhesion molecule targeted nanovesicular drug delivery system

Site-specific delivery of anticancer agents to tumors represents a promising therapeutic strategy because it increases efficacy and reduces toxicity to normal tissues compared with untargeted drugs. Sterically stabilized immunoliposomes (SIL), guided by antibodies that specifically bind to well internalizing antigens on the tumor cell surface, are effective nanoscale delivery systems capable of accumulating large quantities of anticancer agents at the tumor site. The epithelial cell adhesion molecule (EpCAM) holds major promise as a target for antibody-based cancer therapy due to its abundant expression in many solid tumors and its limited distribution in normal tissues. We generated EpCAM-directed immunoliposomes by covalently coupling the humanized single-chain Fv antibody fragment 4D5MOCB to the surface of sterically stabilized liposomes loaded with the anticancer agent doxorubicin. In vitro, the doxorubicin-loaded immunoliposomes (SIL-Dox) showed efficient cell binding and internalization and were significantly more cytotoxic against EpCAM-positive tumor cells than nontargeted liposomes (SL-Dox). In athymic mice bearing established human tumor xenografts, pharmacokinetic and biodistribution analysis of SIL-Dox revealed long circulation times in the blood with a half-life of 11 h and effective time-dependent tumor localization, resulting in up to 15% injected dose per gram tissue. These favorable pharmacokinetic properties translated into potent antitumor activity, which resulted in significant growth inhibition (compared with control mice), and was more pronounced than that of doxorubicin alone and nontargeted SL-Dox at low, nontoxic doses. Our data show the promise of EpCAM-directed nanovesicular drug delivery for targeted therapy of solid tumors.

Marine cyanobacteria compounds with anticancer properties: a review on the implication of apoptosis

Marine cyanobacteria have been considered a rich source of secondary metabolites with potential biotechnological applications, namely in the pharmacological field. Chemically diverse compounds were found to induce cytoxicity, anti-inflammatory and antibacterial activities. The potential of marine cyanobacteria as anticancer agents has however been the most explored and, besides cytotoxicity in tumor cell lines, several compounds have emerged as templates for the development of new anticancer drugs. The mechanisms implicated in the cytotoxicity of marine cyanobacteria compounds in tumor cell lines are still largely overlooked but several studies point to an implication in apoptosis. This association has been related to several apoptotic indicators such as cell cycle arrest, mitochondrial dysfunctions and oxidative damage, alterations in caspase cascade, alterations in specific proteins levels and alterations in the membrane sodium dynamics. In the present paper a compilation of the described marine cyanobacterial compounds with potential anticancer properties is presented and a review on the implication of apoptosis as the mechanism of cell death is discussed.

Review of therapeutic drug monitoring of anticancer drugs part one - Cytotoxics.

Most anticancer drugs are characterised by a steep dose-response relationship and narrow therapeutic window. Inter-individual pharmacokinetic (PK) variability is often substantial. The most relevant PK parameter for cytotoxic drugs is the area under the plasma concentration versus time curve (AUC). Thus it is somewhat surprising that therapeutic drug monitoring (TDM) is still uncommon for the majority of agents. Goals of the review were to assess the rationale for more widely used TDM of cytotoxics in oncology. There are several reasons why TDM has never been fully implemented into daily oncology practice. These include difficulties in establishing appropriate concentration target ranges, common use of combination chemotherapies for many tumour types, analytical challenges with prodrugs, intracellular compounds, the paucity of published data from pharmacological trials and 'Day1=Day21' administration schedules. There are some specific situations for which these limitations are overcome, including high dose methotrexate, 5-fluorouracil infusion, mitotane and some high dose chemotherapy regimens. TDM in paediatric oncology represents an important challenge. Established TDM approaches includes the widely used anticancer agents carboplatin, busulfan and methotrexate, with 13-cis-retinoic acid also recently of interest. Considerable effort should be made to better define concentration-effect relationships and to utilise tools such as population PK/PD models and comparative randomised trials of classic dosing versus pharmacokinetically guided adaptive dosing. There is an important heterogeneity among clinical practices and a strong need to promote TDM guidelines among the oncological community.

Epigenetic deregulation of DNA repair and its potential for therapy.

Epigenetic silencing of essential components of DNA repair pathways is a common event in many tumor types, and comprise O6-methylguanine-DNA methyltransferase (MGMT), human mut L homolog 1 (hMLH1), Werner syndrome gene (WRN), breast cancer susceptibility gene 1 (BRCA1), and genes of the Fanconi anemia pathway. Most interestingly, some of these alterations become the Achilles heel of the affected tumors upon treatment with certain classes of anticancer agents. That is, patients whose tumors carry such defects can be stratified for respective therapy rendering some classic DNA damaging agents, such as alkylators or DNA crosslinking agents, into "targeted therapies." Here we review some of the affected repair pathways that, when inactivated, sensitize the tumors to specific drugs and are thus exploitable for individualized therapy.

Prostate-targeted radiosensitization via aptamer-shRNA chimeras in human tumor xenografts

Dose-escalated radiation therapy for localized prostate cancer (PCa) has a clear therapeutic benefit; however, escalated doses may also increase injury to noncancerous tissues. Radiosensitizing agents can improve ionizing radiation (IR) potency, but without targeted delivery, these agents will also sensitize surrounding normal tissues. Here we describe the development of prostate-targeted RNAi agents that selectively sensitized prostate-specific membrane antigen–positive (PSMA-positive) cells to IR. siRNA library screens identified DNA-activated protein kinase, catalytic polypeptide (DNAPK) as an ideal radiosensitization target. DNAPK shRNAs, delivered by PSMA-targeting RNA aptamers, selectively reduced DNAPK in PCa cells, xenografts, and human prostate tissues. Aptamer-targeted DNAPK shRNAs, combined with IR, dramatically and specifically enhanced PSMA-positive tumor response to IR. These findings support aptamer-shRNA chimeras as selective sensitizing agents for the improved treatment of high-risk localized PCa.

Combined drug action of 2-phenylimidazo[2,1-b]benzothiazole derivatives on cancer cells according to their oncogenic molecular signatures

The development of targeted molecular therapies has provided remarkable advances into the treatment of human cancers. However, in most tumors the selective pressure triggered by anticancer agents encourages cancer cells to acquire resistance mechanisms. The generation of new rationally designed targeting agents acting on the oncogenic path(s) at multiple levels is a promising approach for molecular therapies. 2-phenylimidazo[2,1-b]benzothiazole derivatives have been highlighted for their properties of targeting oncogenic Met receptor tyrosine kinase (RTK) signaling. In this study, we evaluated the mechanism of action of one of the most active imidazo[2,1-b]benzothiazol-2-ylphenyl moiety-based agents, Triflorcas, on a panel of cancer cells with distinct features. We show that Triflorcas impairs in vitro and in vivo tumorigenesis of cancer cells carrying Met mutations. Moreover, Triflorcas hampers survival and anchorage-independent growth of cancer cells characterized by 'RTK swapping' by interfering with PDGFRβ phosphorylation. A restrained effect of Triflorcas on metabolic genes correlates with the absence of major side effects in vivo. Mechanistically, in addition to targeting Met, Triflorcas alters phosphorylation levels of the PI3K-Akt pathway, mediating oncogenic dependency to Met, in addition to Retinoblastoma and nucleophosmin/B23, resulting in altered cell cycle progression and mitotic failure. Our findings show how the unusual binding plasticity of the Met active site towards structurally different inhibitors can be exploited to generate drugs able to target Met oncogenic dependency at distinct levels. Moreover, the disease-oriented NCI Anticancer Drug Screen revealed that Triflorcas elicits a unique profile of growth inhibitory-responses on cancer cell lines, indicating a novel mechanism of drug action. The anti-tumor activity elicited by 2-phenylimidazo[2,1-b]benzothiazole derivatives through combined inhibition of distinct effectors in cancer cells reveal them to be promising anticancer agents for further investigation.

Combined drug action of 2-phenylimidazo[2,1-b]benzothiazole derivatives on cancer cells according to their oncogenic molecular signatures

The development of targeted molecular therapies has provided remarkable advances into the treatment of human cancers. However, in most tumors the selective pressure triggered by anticancer agents encourages cancer cells to acquire resistance mechanisms. The generation of new rationally designed targeting agents acting on the oncogenic path(s) at multiple levels is a promising approach for molecular therapies. 2-phenylimidazo[2,1-b]benzothiazole derivatives have been highlighted for their properties of targeting oncogenic Met receptor tyrosine kinase (RTK) signaling. In this study, we evaluated the mechanism of action of one of the most active imidazo[2,1-b]benzothiazol-2-ylphenyl moiety-based agents, Triflorcas, on a panel of cancer cells with distinct features. We show that Triflorcas impairs in vitro and in vivo tumorigenesis of cancer cells carrying Met mutations. Moreover, Triflorcas hampers survival and anchorage-independent growth of cancer cells characterized by 'RTK swapping' by interfering with PDGFRβ phosphorylation. A restrained effect of Triflorcas on metabolic genes correlates with the absence of major side effects in vivo. Mechanistically, in addition to targeting Met, Triflorcas alters phosphorylation levels of the PI3K-Akt pathway, mediating oncogenic dependency to Met, in addition to Retinoblastoma and nucleophosmin/B23, resulting in altered cell cycle progression and mitotic failure. Our findings show how the unusual binding plasticity of the Met active site towards structurally different inhibitors can be exploited to generate drugs able to target Met oncogenic dependency at distinct levels. Moreover, the disease-oriented NCI Anticancer Drug Screen revealed that Triflorcas elicits a unique profile of growth inhibitory-responses on cancer cell lines, indicating a novel mechanism of drug action. The anti-tumor activity elicited by 2-phenylimidazo[2,1-b]benzothiazole derivatives through combined inhibition of distinct effectors in cancer cells reveal them to be promising anticancer agents for further investigation.

Systèmes vésiculaires colloïdaux pour la vectorisation de la 1-β-D-arabinofuranosylcytosine

La 1-β-D-arabinofuranosylcytosine (ara-C) demeure l’agent anticancéreux principalement utilisé dans le traitement de la leucémie myéloblastique aiguë (LMA), malgré sa dégradation et son élimination rapide après une administration parentérale. Son encapsulation dans des vecteurs pharmaceutiques, majoritairement des liposomes, a permis de surmonter ces inconvénients. L’objectif général de ce projet de doctorat était de développer deux systèmes à libération prolongée, à base de phospholipides, de cholestérol et de poly(éthylène glycol) (PEG) afin d’encapsuler l’ara-C et ultimement, d’améliorer son efficacité dans le traitement de la LMA. Des Sphérulites® (vésicules multilamellaires d’un type particulier) ont d’abord été étudiées pour leur forte capacité d’encapsulation, due à leur mode de préparation. Par la suite, une formulation liposomale capable, d’une part de cibler spécifiquement les cellules leucémiques et, d’autre part, de promouvoir la libération intracellulaire de l’ara-C grâce à sa sensibilité au pH, a été mise au point. Les deux formulations se devaient d’avoir un faible diamètre, une stabilité en présence de fluides biologiques et des temps de circulation prolongés chez l’animal. Une préparation de Sphérulites®, composée de Phospholipon 90G, de Solutol HS15 et de cholestérol, a permis d’obtenir des vésicules de 300 nm de diamètre. Un dérivé lipidique de PEG a pu être fixé à leur surface, sans modifier la disposition concentrique des lamelles, ni changer leur stabilité. Les Sphérulites® PEGylées ont été chargées d’ara-C et injectées chez le rat par la voie intraveineuse. Elles ont démontré des temps de circulation significativement prolongés comparativement aux Sphérulites® sans PEG. Cependant, l’ara-C s’est retrouvée éliminée de la circulation sanguine très rapidement, révélant une libération précoce du principe actif à partir de ces vésicules. Les liposomes sensibles au pH (~150 nm) ont été obtenus suite à l’insertion d’un copolymère à base de dioctadécyle, de N-isopropylacrylamide (NIPAM) et d’acide méthacrylique. L’anticorps anti-CD33, soit complet soit son fragment Fab’, a été fixé à la surface des liposomes afin de cibler les cellules leucémiques. Les essais in vitro ont démontré la spécificité de la formulation pour différentes cellules leucémiques (CD33+), sa stabilité en présence de protéines plasmatiques et la libération intracellulaire d’un marqueur fluorescent et de l’ara-C. Enfin, des études menées chez la souris saine et immunodéprimée inoculée de cellules HL60 ont montré que la formulation exposant le fragment Fab’ possédait un profil pharmacocinétique et une biodistribution semblables à ceux des liposomes contrôles non-ciblés. L’encapsulation de l’ara-C a permis d’améliorer grandement ses temps de circulation après une administration intraveineuse. Cependant, bien que les immunoliposomes ont permis de prolonger la survie des souris leucémiques comparativement à l’ara-C libre, l’addition du polymère sensible au pH n’a pas permis d’apporter de réel avantage à la formulation lorsque administrée in vivo. Les résultats obtenus dans ce travail de thèse ont, dans un premier temps, mis en évidence que les Sphérulites® pourraient s’avérer utiles dans la vectorisation d’agents anticancéreux si leur capacité à retenir le principe actif in vivo était améliorée. Dans un second temps, les données présentées avec les immunoliposomes suggèrent qu’ils pourraient apporter un bénéfice notable dans le traitement de la LMA.

Mise au point de nanoparticules polymères pour l'administration parentérale d'agents anticancéreux hydrophobes

Plusieurs agents anticancéreux très puissants sont caractérisés par une solubilité aqueuse limitée et une toxicité systémique importante. Cette dernière serait liée d’une part à la solubilisation des agents anticancéreux à l’aide de surfactifs de bas poids moléculaire, connus pour leur toxicité intrinsèque, et d’autre part, par le manque de spécificité tissulaire des anticancéreux. Les vecteurs colloïdaux à base de polymères permettraient de résoudre certains défis liés à la formulation d’agents anticancéreux hydrophobes. D’abord, les polymères peuvent être sélectionnés afin de répondre à des critères précis de compatibilité, de dégradation et d’affinité pour le médicament à formuler. Ensuite, le fait d’encapsuler l’agent anticancéreux dans un vecteur peut améliorer son efficacité thérapeutique en favorisant son accumulation au niveau du tissu cible, i.e. la tumeur, et ainsi limiter sa distribution au niveau des tissus sains. Des travaux antérieurs menés au sein de notre laboratoire ont mené à la mise au point de micelles à base de poly(N-vinyl-pyrrolidone)-bloc-poly(D,L-lactide) (PVP-b-PDLLA) capables de solubiliser des agents anticancéreux faiblement hydrosolubles dont le PTX. Ce dernier est commercialisé sous le nom de Taxol® et formulé à l’aide du Crémophor EL (CrEL), un surfactif de bas poids moléculaire pouvant provoquer, entre autres, des réactions d’hypersensibilité sévères. Bien que les micelles de PVP-b-PDLLA chargées de PTX aient démontré une meilleure tolérance comparée au Taxol®, leur potentiel de ciblage tumoral et leur efficacité thérapeutique étaient similaires à la forme commerciale à doses égales. Ceci était possiblement dû au fait que les micelles étaient rapidement déstabilisées et ne pouvaient retenir leur cargo suite à leur administration intraveineuse. Nous avons donc décidé de poursuivre les travaux avec un autre type de vecteur, soit des nanoparticules, qui possèdent une stabilité intrinsèque supérieure aux micelles. L’objectif principal de cette thèse de doctorat était donc de mettre au point des nanoparticules polymères pour l’administration parentérale d’agents anticancéreux faiblement solubles dans l’eau. Les nanoparticules devaient permettre d’encapsuler des agents anticancéreux hydrophobes et de les libérer de manière contrôlée sur plusieurs jours. De plus, elles devaient démontrer un temps de circulation plasmatique prolongée afin de favoriser l’accumulation passive du médicament encapsulé au niveau de la tumeur. La première partie du travail visait à employer pour la première fois le copolymère amphiphile PVP-b-PDLLA comme émulsifiant dans la préparation de nanoparticules polymères. Ainsi, une méthode de fabrication des nanoparticules par émulsion huile-dans-eau a été appliquée afin de produire des nanoparticules à base de PDLLA de taille inférieure à 250 nm. Grâce aux propriétés lyoprotectrices de la couronne de PVP présente à la surface des nanoparticules, celles-ci pouvaient retrouver leur distribution de taille initiale après lyophilisation et redispersion en milieu aqueux. Deux anticancéreux hydrophobes, soit le PTX et l’étoposide (ETO), ont été encapsulés dans les nanoparticules et libérés de ces dernières de façon contrôlée sur plusieurs jours in vitro. Une procédure de « salting-out » a été appliquée afin d’améliorer le taux d’incorporation de l’ETO initialement faible étant donnée sa solubilité aqueuse légèrement supérieure à celle du PTX. Le second volet des travaux visait à comparer le PVP comme polymère de surface des nanoparticules au PEG, le polymère le plus fréquemment employé à cette fin en vectorisation. Par le biais d’études d’adsorption de protéines, de capture par les macrophages et de biodistribution chez le rat, nous avons établi une corrélation in vitro/in vivo démontrant que le PVP n’était pas un agent de surface aussi efficace que le PEG. Ainsi, malgré la présence du PVP à la surface des nanoparticules de PDLLA, ces dernières étaient rapidement éliminées de la circulation sanguine suite à leur capture par le système des phagocytes mononucléés. Par conséquent, dans le troisième volet de cette thèse, le PEG a été retenu comme agent de surface, tandis que différents polymères biodégradables de la famille des polyesters, certains synthétiques (PDLLA et copolymères d’acide lactique/acide glycolique), d’autres de source naturelle (poly(hydroxyalkanoates)(PHAs)), ont été investiguées comme matériaux formant le cœur des nanoparticules. Il en est ressorti que les propriétés physicochimiques des polyesters avaient un impact majeur sur l’efficacité d’encapsulation du PTX et son profil de libération des nanoparticules in vitro. Contrairement aux PHAs, les polymères synthétiques ont démontré des taux d’incorporation élevés ainsi qu’une libération contrôlée de leur cargo. Des études de pharmacocinétique et de biodistribution ont démontré que les nanoparticules de PDLLA dotées d’une couronne de PEG conféraient un temps de circulation plasmatique prolongé au PTX et favorisaient son accumulation tumorale. Les nanoparticules polymères représentent donc une alternative intéressante au Taxol®.

Combination therapy: opportunities and challenges for polymer-drug conjugates as anticancer nanomedicines.

The discovery of new molecular targets and the subsequent development of novel anticancer agents are opening new possibilities for drug combination therapy as anticancer treatment. Polymer-drug conjugates are well established for the delivery of a single therapeutic agent, but only in very recent years their use has been extended to the delivery of multi-agent therapy. These early studies revealed the therapeutic potential of this application but raised new challenges (namely, drug loading and drugs ratio, characterisation, and development of suitable carriers) that need to be addressed for a successful optimisation of the system towards clinical applications.

Are class II phosphoinositide 3-kinases potential targets for anticancer therapies?

Of the three classes of true phosphoinositide (PI) 3-kinases, the class II subdivision, which consists of three isoforms, PI3K-C2alpha, PI3K-C2beta and PI3K-C2gamma, is the least well understood. There are a number of reasons for this. This class of PI 3-kinase was identified exclusively by PCR and homology cloning approaches and not on the basis of cellular function. Like class I PI 3-kinases, class II PI 3-kinases are activated by diverse receptor types. To complicate the elucidation of class II PI 3-kinase function further, their in vitro substrate specificity is intermediate between the receptor activated class I PI 3-kinases and the housekeeping class III PI 3-kinase. The class II PI 3-kinases are inhibited by the two commonly used PI 3-kinase family selective inhibitors, wortmannin and LY294002, and there are no widely available, specific inhibitors for the individual classes or isoforms. Here the current state of understanding of class II PI 3-kinase function is reviewed, followed by an appraisal as to whether there is enough evidence to suggest that pharmaceutical companies, who are currently targeting the class I PI 3-kinases in an attempt to generate anticancer agents, should also consider targeting the class II PI 3-kinases.

Exploring quercetin and luteolin derivatives as antiangiogenic agents

The formation of new blood vessels from the pre-existing vasculature (angiogenesis) is a crucial stage in cancer progression and, indeed, angiogenesis inhibitors are now used as anticancer agents, clinically. Here we have explored the potential of flavonoid derivatives as antiangiogenic agents. Specifically, we have synthesised methoxy and 4-thio derivatives of the natural flavones quercetin and luteolin, two of which (4-thio quercetin and 4-thio luteolin) had never been previously reported. Seven of these compounds showed significant (P<0.05) antiangiogenic activity in an in vitro scratch assay. Their activity ranged from an 86% inhibition of the vascular endothelium growth factor (VEGF)-stimulated migration (observed for methoxyquercetin at 10 µM and for luteolin at 1 µM) to a 36% inhibition (for thiomethoxy quercetin at 10 µM). Western blotting studies showed that most (4 out of 7) compounds inhibited phosphorylation of the VEGF receptor-2 (VEGFR2), suggesting that the antiangiogenic activity was due to an interference with the VEGF/VEGFR2 pathway. Molecular modelling studies looking at the affinity of our compounds towards VEGFR and/or VEGF confirmed this hypothesis, and indeed the compound with the highest antiangiogenic activity (methoxyquercetin) showed the highest affinity towards VEGFR and VEGF. As reports from others have suggested that structurally similar compounds can elicit biological responses via a non-specific, promiscuous membrane perturbation, potential interactions of the active compounds with a model lipid bilayer were assessed via DSC. Luteolin and its derivatives did not perturb the model membrane even at concentrations 10 times higher than the biologically active concentration and only subtle interactions were observed for quercetin and its derivatives. Finally, cytotoxicity assessment of these flavonoid derivatives against MCF-7 breast cancer cells demonstrated also a direct anticancer activity albeit at generally higher concentrations than those required for an antiangiogenic effect (10 fold higher for the methoxy analogues). Taken together these results show promise for flavonoid derivatives as antiangiogenic agents.