Enhancing Cardiomyocyte Survival in Drug Induced Cardiac Injury

Maharsy, Wael

11 October 2012

Cardiotoxicity associated with many cancer drugs is a critical issue facing physicians these days and a huge hurdle that must be overcome for a side effects-free cancer therapy. Survival of cardiac myocytes is compromised upon the exposure to certain chemotherapeutic drugs. Unfortunately, the mechanisms implicated in cardiac toxicity and the pathways governing myocyte survival are poorly understood. The following thesis addresses the mechanisms underlying the cardiotoxicity of two anticancer drugs, doxorubicin (DOX) and Imatinib mesylate (Gleevec). Transcription factor GATA-4, has recently emerged as an indispensable factor in the adult heart adaptive response and cardiomyocyte survival. Therefore, the specific aim of this project was to determine the role of GATA-4, its upstream regulators, as well as partners in survival. A combination of cell and molecular techniques done on in vivo, and ex vivo models were utilized to tackle these issues. In this study, we confirmed the cardiotoxicity of the anticancer drug, Imatinib mesylate and found to be age dependent. GATA-4, already known to be implicated in DOX-induced toxicity, was confirmed as an Imatinib target. At the molecular level, we identified IGF-1 and AKT as upstream regulators of GATA-4. Moreover, we confirmed ZFP260 (PEX-1), a key regulator of the cardiac hypertrophic response, as a GATA-4 collaborator in common prosurvival pathways. Collectively, these results provide new insights on the mechanisms underlying drug-induced cardiotoxicity and raise the exciting possibility that cancer drugs are negatively affecting the same prosurvival pathway(s), in which GATA-4 is a critical component. Therapeutic interventions aimed at enhancing GATA-4 activity may be interesting to consider in the context of treatments with anticancer drugs.

Heart

Heart Failure

Cancer

Cardiomyopathy

Cardiotoxicity

Anticancer drugs

Doxorubicin

Imatinib

Self-Assembling Peptides as Potential Carriers for the Delivery of the Hydrophobic Anticancer Agent Ellipticine

Fung, Shan-Yu

January 2008

Self-assembling peptides have emerged as new nanobiomaterials in the areas of nanoscience and biomedical engineering. In this category are self-assembling, ionic-complementary peptides, which contain a repeating charge distribution and alternating hydrophobic and hydrophilic residues in the amino acid sequence, leading to a unique combination of amphiphilicity and ionic complementarity. These peptides can self-assemble into stable nanostructures or macroscopic membranes that can withstand conditions of high temperature, extreme pH, many digesting enzymes and denaturation agents. Moreover, they exhibit good biocompatibility with various cultured mammalian cells, and do not have detectable immune responses when introduced into animals. These properties make them ideal materials for tissue scaffolding, regenerative medicine and drug delivery. This thesis focuses on the utilization of self-assembling peptides for hydrophobic anticancer drug delivery. The hydrophobic anticancer agent ellipticine was selected as a model drug. The studies include: (i) characterization of the photophysical properties of ellipticine in different environments; (ii) study of the formation of peptide-ellipticine complexes and the release kinetics; (iii) investigation of the cellular toxicity of the complexes and ellipticine uptake; (iv) study of the peptide sequence effect on the complex formation and in vitro delivery. Prior to applying ellipticine to the peptide-based delivery system, the fundamental studies on the effect of solution conditions, especially solvent polarity and hydrogen bonding, on the fluorescence of ellipticine were carried out. Ultraviolet (UV) absorption and fluorescence emission of ellipticine were found to be solvent/environment dependent. The absorption and emission maxima shifted to higher wavelengths (red shift) with increased solvent polarity. Large Stokes’ shifts were due to intramolecular charge transfer (ICT), which was enabled by large solvent polarity and hydrogen bonding of ellipticine with the solvents. The photophysical response of ellipticine to changes in solvent polarity and hydrogen bond formation could be used to infer the location of ellipticine in a heterogeneous medium, such as liposomes and cultured cells. EAK16-II, a model self-assembling peptide, was found to be able to stabilize ellipticine in aqueous solution. The equilibration time required to form peptide-ellipticine complex suspensions was found to be peptide concentration-dependent and related to the peptide critical aggregation concentration (CAC, ~0.1 mg/mL). With different combinations of EAK16-II and ellipticine concentrations, two molecular states (protonated or crystalline) of ellipticine could be obtained in the complexes. The release kinetics of ellipticine from the complex into egg phosphatidylcholine (EPC) vesicles (cell membrane mimics) was also affected by the peptide concentration used in the drug formulation. A higher peptide concentration resulted in a faster transfer rate, in relation to the size of the resulting complexes. Subsequent cellular studies on two cancer cell lines, A549 and MCF-7, showed that the complexes with protonated ellipticine were more effective against both cell lines, but their dilutions were not very stable. In addition, it was found that ellipticine uptake in both cell lines was very fast and through direct membrane permeation. Three peptides, EAK16-II, EAK16-IV and EFK16-II, either having a different charge distribution (EAK16-II vs. EAK16-IV) or hydrophobicity (EAK16-II vs. EFK16-II), were tested for the complexation and in vitro delivery of ellipticine. It was found that EAK16-II and EAK16-IV were able to stabilize protonated or crystalline ellipticine depending on the peptide concentration; EFK16-II, on the other hand, could stabilize neutral ellipticine molecules and ellipticine (micro)crystals. The viability results showed that the charge distribution of the peptides seemed not to affect the complex formation and its therapeutic efficacy in vitro; however, the increase in hydrophobicity of the peptides significantly altered the states of stabilized ellipticine and increased the stability of the complexes. This work provides essential information for peptide sequence design in the development of self-assembling peptide-based delivery of hydrophobic anticancer drugs.

self-assembling peptides

anticancer drug delivery

Chemical Engineering

Copper-transporting proteins and their interactions with platinum-based anticancer substances

Espling, Maria

January 2013

Cisplatin (CisPt) is an important drug that is used against various cancers, including testicular, ovarian, lung, head, and neck cancer. However, its effects are limited by cellular resistance. The resistance is believed to be multifactorial, and may be mediated to varying degree by multiple systems in cells, one of the proposed systems being the copper (Cu) transporting system. The Cu-importer Ctr1 has proven importance for cellular sensitivity to CisPt by regulating its influx, while the Golgi-localized Cu-ATP:ases ATP7A/B can putatively mediate CisPt efflux and/or drug sequestration. Atox1 is a small Cu-chaperone that normally transfers Cu between Ctr1 and ATP7A/B, prior to delivery of Cu to the proteins in the secretory pathway. Since Ctr1 and ATP7A/B are reportedly involved in CisPt-resistance, CisPt interaction with Atox1 was the focus of the project this thesis is based upon.   Using a variety of techniques, Atox1 was found to bind CisPt, also simultaneously with Cu. The Atox1-CisPt complexes were further probed using selected mutants in studies demonstrating that only the two cysteines (Cys12 and Cys15) in the Cu-binding site of Atox1 are essential for CisPt interactions. A proposed Atox1 di-metal complex containing both Cu and CisPt was found to be monomeric, and no loss of Cu was observed. In vitro experiments demonstrated that CisPt could also bind to metal-binding domain 4 of ATP7B (WD4), and that the drug could be transferred from Atox1 to the domain. These findings indicated that Atox1 may transfer CisPt to ATP7A/B in vivo, utilizing the same transport pathway as Cu. However, the CisPt-bound Atox1 complexes were not stable over time; upon incubation, protein unfolding and aggregation were observed. Thus, in vivo, Atox1 might alternatively be a dead-end sink for CisPt.   The effects of the ligands around the Pt-center of Pt-based anticancer drugs and drug derivatives on Atox1 binding and unfolding were also investigated. The ligands’ chemistry and geometry were shown to dictate the extent and rate of the Pt-based substances interactions with Atox1. Finally, the occurrence of Atox1-CisPt interactions in a biological environment was demonstrated by developing and applying an antibody-based method allowing analysis of metals associated with Atox1 extracted from CisPt-treated cells.   The findings presented in this thesis show that CisPt binds to Atox1 and WD4, also simultaneously with Cu, in vitro. The results support the hypothesis that Cu-transporting proteins can mediate cellular resistance to CisPt in vivo, and provide a deeper chemical understanding of the interactions between the proteins and the drug.

Cisplatin

Atox1

copper transport

anticancer drug

resistance

platinum

spectroscopy.

Self-Assembling Peptides as Potential Carriers for the Delivery of the Hydrophobic Anticancer Agent Ellipticine

Fung, Shan-Yu

January 2008

Self-assembling peptides have emerged as new nanobiomaterials in the areas of nanoscience and biomedical engineering. In this category are self-assembling, ionic-complementary peptides, which contain a repeating charge distribution and alternating hydrophobic and hydrophilic residues in the amino acid sequence, leading to a unique combination of amphiphilicity and ionic complementarity. These peptides can self-assemble into stable nanostructures or macroscopic membranes that can withstand conditions of high temperature, extreme pH, many digesting enzymes and denaturation agents. Moreover, they exhibit good biocompatibility with various cultured mammalian cells, and do not have detectable immune responses when introduced into animals. These properties make them ideal materials for tissue scaffolding, regenerative medicine and drug delivery. This thesis focuses on the utilization of self-assembling peptides for hydrophobic anticancer drug delivery. The hydrophobic anticancer agent ellipticine was selected as a model drug. The studies include: (i) characterization of the photophysical properties of ellipticine in different environments; (ii) study of the formation of peptide-ellipticine complexes and the release kinetics; (iii) investigation of the cellular toxicity of the complexes and ellipticine uptake; (iv) study of the peptide sequence effect on the complex formation and in vitro delivery. Prior to applying ellipticine to the peptide-based delivery system, the fundamental studies on the effect of solution conditions, especially solvent polarity and hydrogen bonding, on the fluorescence of ellipticine were carried out. Ultraviolet (UV) absorption and fluorescence emission of ellipticine were found to be solvent/environment dependent. The absorption and emission maxima shifted to higher wavelengths (red shift) with increased solvent polarity. Large Stokes’ shifts were due to intramolecular charge transfer (ICT), which was enabled by large solvent polarity and hydrogen bonding of ellipticine with the solvents. The photophysical response of ellipticine to changes in solvent polarity and hydrogen bond formation could be used to infer the location of ellipticine in a heterogeneous medium, such as liposomes and cultured cells. EAK16-II, a model self-assembling peptide, was found to be able to stabilize ellipticine in aqueous solution. The equilibration time required to form peptide-ellipticine complex suspensions was found to be peptide concentration-dependent and related to the peptide critical aggregation concentration (CAC, ~0.1 mg/mL). With different combinations of EAK16-II and ellipticine concentrations, two molecular states (protonated or crystalline) of ellipticine could be obtained in the complexes. The release kinetics of ellipticine from the complex into egg phosphatidylcholine (EPC) vesicles (cell membrane mimics) was also affected by the peptide concentration used in the drug formulation. A higher peptide concentration resulted in a faster transfer rate, in relation to the size of the resulting complexes. Subsequent cellular studies on two cancer cell lines, A549 and MCF-7, showed that the complexes with protonated ellipticine were more effective against both cell lines, but their dilutions were not very stable. In addition, it was found that ellipticine uptake in both cell lines was very fast and through direct membrane permeation. Three peptides, EAK16-II, EAK16-IV and EFK16-II, either having a different charge distribution (EAK16-II vs. EAK16-IV) or hydrophobicity (EAK16-II vs. EFK16-II), were tested for the complexation and in vitro delivery of ellipticine. It was found that EAK16-II and EAK16-IV were able to stabilize protonated or crystalline ellipticine depending on the peptide concentration; EFK16-II, on the other hand, could stabilize neutral ellipticine molecules and ellipticine (micro)crystals. The viability results showed that the charge distribution of the peptides seemed not to affect the complex formation and its therapeutic efficacy in vitro; however, the increase in hydrophobicity of the peptides significantly altered the states of stabilized ellipticine and increased the stability of the complexes. This work provides essential information for peptide sequence design in the development of self-assembling peptide-based delivery of hydrophobic anticancer drugs.

self-assembling peptides

anticancer drug delivery

Chemical Engineering

New mechanism-based anticancer drugs that act as orphan nuclear receptor agonists

Chintharlapalli, Sudhakar Reddy

17 September 2007

1,1-Bis(3'-indolyl)-1-(p-substitutedphenyl)methanes containing ptrifluoromethyl (DIM-C-pPhCF3), p-t-butyl (DIM-C-pPhtBu), and phenyl (DIM-CpPhC6H5) substituents have been identified as a new class of peroxisome proliferatoractivated receptor γ (PPARγ) agonists that exhibit antitumorigenic activity. In this study, the PPARγ-active compounds decreased HT-29, HCT-15, RKO, HCT116 and SW480 colon cancer cell survival and KU7 and 253JB-V33 bladder cancer cell survival. In HT- 29, HCT-15, SW480 and KU7 cells, the PPARγ agonists induced caveolin-1 expression and this induction was significantly downregulated after cotreatment with the PPARγ antagonist GW9662. Since overexpression of caveolin-1 is known to suppress cancer cell and tumor growth, the growth inhibitory effects of the DIM compounds in these cell lines are associated with PPARγ-dependent induction of caveolins. These PPARγ-active compounds did not induce caveolin-1 in HCT-116 cells. However, these compounds induced NSAID-activated gene-1 (NAG-1) and apoptosis in this cell line. This represents a novel receptor-independent pathway for C-DIM-induced growth inhibition and apoptosis in colon cancer cells. In SW480 colon cancer cells 2.5-7.5 μM C-DIMs induced caveolin-1 whereas high concentrations (10 μM) induced pro-apoptotic NAG-1 expression. In athymic nude mice bearing SW480 cell xenografts DIM-C-pPhC6H5 inhibited tumor growth and immunohistochemical staining of the tumors show induction of apoptosis and NAG-1 expression. Thus, the PPARγ-active compounds induce both receptor-dependent and-independent responses in SW480 cells which are separable over a narrow range of concentrations and this dual mechanism of action enhances their antiproliferative and anticancer activities. Similar results were obtained for another structural class of PPARγ agonists namely 2-cyano-3,12-dioxoolean-1,9-dien-28-oic acid (CDDO) and the corresponding methyl (CDDO-Me) and imidazole (CDDO-Im) esters. Structure-activity studies show that 1,1-bis(3'-indolyl)-1-(psubstitutedphenyl) methanes containing p-trifluoromethyl (DIM-C-pPhCF3), hydrogen (DIM-C-pPh) and p-methoxy (DIM-C-pPhOCH3) substituents activate Nur77 and induce apoptosis in pancreatic, prostate, and breast cancer cell lines. Nur77 agonists activate the nuclear receptor, and downstream responses include decreased cell survival, induction of cell death pathways including tumor necrosis factor related apoptosis-inducing ligand (TRAIL) and PARP cleavage. Nur77 agonists also inhibit tumor growth in vivo in athymic nude mice bearing Panc-28 cell xenografts.

C-DIMs

PPAR gamma

Nur77

Apoptosis

Anticancer Drugs

Caveolin-1

Expanded porphyrins as experimental anticancer agents and MRI contrast agents

Preihs, Christian

04 March 2014

Texaphyrins represent the vanguard of experimental anticancer drugs and also symbolize a well-known example of expanded porphyrins, a class of oligopyrrolic macrocycles with tumor localization properties and powerful metal chelating properties. Chapter 1 of this thesis describes the unique structural characteristics of this complex synthetic molecule along with the biological relevance and scientific justifications for studying its anticancer properties and powerful MRI contrast ability. This Chapter also serves to underscore the need to improve further and refine the efficacy of texaphyrins as compounds that may be applied in the struggle against cancer. Chapter 2 details the synthesis of bismuth(III) and lead(II)-texaphyrin complexes that could potentially find use as [alpha]-core emitters for radiotherapy. In principle, porphyrins would ostensibly appear to be ideal ligands for use in radiotherapy due to their tumor-localizing ability. However, Bi(III)- and Pb(II)-porphyrin complexes are extremely rare, most reflecting the vastly challenging synthesis of these compounds as well as their general lack of stability. These limitations provided an incentive for us to use texaphyrins as more versatile ligands to prepare and fully characterize stable bismuth(III) and lead(II) complexes. To be of interest in future medical applications, we needed to prepare these complexes quickly as compared to the relevant time scales set by the half-lives of the isotopes targeted for use in radiotherapy. This goal was successfully realized. As mentioned above, texaphyrin is able to form stable complexes with a large variety of metals particularly in the lanthanide series. Gadolinium(III) complexes of texaphyrin have been studied in considerable detail. Chapter 3 details the synthesis and conjugation methods used to develop a texaphyrin conjugated dual mode nanoparticle contrast agent. This project has been done in collaboration with the group of Prof. Jinwoo Cheon (Yonsei University, Seoul, Korea), who demonstrated fascinating results with the texaphyrin functionalized nanoparticles. Not only do these conjugates act as improved magnetic resonance contrast agents displaying enhanced signals in both the T1 and T2 MRI modes, but also serve to sensitize apoptotic hyperthermia. It is this latter, double effector feature, that has been most extensively studied to date. Chapter 4 of this dissertation describes work done in close collaboration with Dr. Natalie Barkey and Dr. David Morse (Moffitt Cancer Center, Tampa, FL) where a gadolinium texaphyrin complex was developed that is able to target the melanocortin 1 receptor (MC1R) when encapsulated in a micellar system. As detailed in this Chapter, these collaborateurs demonstrated that these gadolinium-texaphyrin micelles are able to target MC1R-expressing xenograft tumors in vivo. This work relied on the supply of a new set of texaphyrin derivatives that were prepared and characterized as part of this dissertation work Chapter 5 of this disseration introduces sapphyrins, another class of expanded porphyrins with tumor selectivity. This project is based on the hypothesis that a direct linkage of sapphyrin with an anticancer agent based on ruthenium(II) could improve the efficacy of both compounds. Since sapphyrins exhibit limited ability to form stable complexes with transition metals, an appended 1,10-phenanthroline unit was chosen as an efficient N-donor aromatic ligand for ruthenium(II). Therefore, extensive synthetic efforts were made to form this sapphyrin-1,10-phenanthroline construct in an effort to stabilize a mixed sapphyrin-metallo-phenanthroline complex. Finally, Chapter 6 of this dissertation demonstrates the author's efforts to synthesize a planar rosarin species. Non-aromatic and non-planar rosarins have been known for over two decades. Through structural modification of the compound, namely through linking of both [Beta] positions on the bipyrrole unit, a new planar rosarin species has been synthesized exhibiting Hückel antiaromaticity. / text

Porphyrins

Expanded porphyrins

Anticancer agents

MRI contrast agents

Radioemitters

Antiaromaticity

In vitro studies using curcumin and curcumin analogues as candidate mitochondria-targeting anticancer agents affecting colon cancer cells

2014 September 1900

Curcumin is one of the major curcuminoids produced by the ginger family Zingiberaceae. These curcuminoids possess pharmacological properties that include anticancer activities. We have evaluated some synthetic curcumin analogues that have shown potential as anticancer drugs. These antineoplastic agents bearing the 1,5-diaryl-3-oxo-1,4-pentadienyl pharmacophore are electrophiles which are designed to preferentially react with sulfhydryl groups present in proteins as opposed to amino and hydroxyl groups present in DNA. In previous pilot studies, three derivatives examined in this thesis showed inhibition towards human cancer cell lines such as Molt 4/C8 and CEM T-lymphocytes. In this thesis work, I determined the cytotoxicity of these derivatives and curcumin towards human colon cancer (HCT-116) cells and also normal colon epithelial (CRL-1790) cells, and examined the possible mechanism(s) involved. I hypothesized that they act via induction of reactive oxygen species (ROS) which elicit a transient surge of mitochondrial ROS generation and a phenomenon known as ROS-induced ROS release (RIRR), along with the mitochondrial permeability transition (MPT) and mitochondrion –dependent apoptosis. I asked whether these agents react with some of the key protein thiols in the mitochondria whose oxidation/alkylation results in mitochondrion - dependent apoptosis. NC-2109 and NC-2346 were found to be potent cytotoxic agents based on their GI50 values of 0.87 ± 0.38 μM and 0.90 ± 0.22 μM, respectively, and were more potent than the anticancer drug 5-fluorouracil (GI50 = 5.47 ± 0.55 μM) and curcumin (GI50 = 3.50 ± 0.36 μM). However NC-2109 was found to have a better selectivity towards cancer cells over normal cells (a selectivity index of 18.81 versus 5-FU, curcumin and NC-2346 which had selectivity indices of 1.87, 16.75 and 4.61, respectively). In the investigations of the mechanisms involved, both curcumin and curcumin analogues were able to induce mitochondrial ROS production. Moreover, curcumin and its synthetic counterparts showed a biphasic ROS profile which is most characteristic of RIRR. Treatment with these agents also led to the disruption of the mitochondrial membrane potential, suggesting oxidation of protein thiols and the opening of the mitochondrial permeability transition pore which is an important step to initiate mitochondria-directed apoptosis. This possibility was confirmed based on GSSG/GSH ratios, since curcumin, NC-2346 and NC-2109 all produced a higher GSSG/GSH ratio than the controls. In addition to their ability to depolarize the mitochondrial membrane in HCT-116 cells, that these molecules acted via the mitochondrial pathway were further authenticated based on their ability to induce mitochondrial swelling in rat liver mitochondria. In another part of this thesis I evaluated the involvement of the critical thiol protein adenine nucleotide translocase (ANT), a bifunctional protein that plays a central role in mitochondrial apoptosis. ANT has four different isoforms; ANT1 and ANT3 are proapoptotic, while ANT2 and ANT4 are antiapoptotic and are overexpressed in cancer states. A combination approach using ANT2 siRNA however did not conclusively show whether these agents acted synergistically with ANT2 knockdown to potentiate mitochondria-mediated cell death. An alternative combination approach was the use of carboxyatractyloside (CAT) which binds to and retains ANT in its ‘c’ conformation, exposing thiols and potentially driving a cell towards programmed cell death. The presence of CAT enhanced the ability of curcumin and its synthetic analogs to collapse the mitochondrial membrane potential, an important step in mitochondrial-mediated apoptosis. In conclusion, curcumin and the curcumin analogue NC-2109 were found to be cytotoxic in vitro, towards HCT-116 cells and also showed good selectivity. In addition, these two molecules were found to be ROS inducers, and coincidentally oxidized cellular thiols and caused depolarization of the mitochondrial membrane potential. The results support a mechanism of mitochondrial-mediated cell death upon MPT pore formation (mitochondrial swelling), perhaps involving ANT2. This conclusion was further supported by the potentiation of cell death in the presence of the ANT2 inhibitor, CAT.

The potential role of TOP2B in therapy-related leukaemia

Smith, Kayleigh Ann

January 2012

No description available.

616.99419

Chemical reactivity and biological activity of bethoxazin, an industrial microbicide

Alrushaid, Samaa

January 2012

Bethoxazin is a broad spectrum industrial biocide with commercial applications as a material preservative; however its mechanism of action has not been investigated. In this study, the chemical reactivity of bethoxazin towards biologically important nucleophiles was assessed with UV-Vis spectroscopy. Bethoxazin reacted with molecules containing free sulfhydryl groups such as glutathione and human serum albumin but not with amino, acetate or phenol containing compounds. Bethoxazin was shown to potently inhibit the growth of the K562 human cancer cell line with an IC50 value in the micromolar range. The sulfydryl fluorescent label ThioGlo-1 was used to investigate the biological effects of bethoxazin in K562 cells and explore its mechanism of action. Bethoxazin inhibited the formation of covalent adducts in K562 cells between the free sulfhydryl group of biomolecules and ThioGlo-1, implying that bethoxazin reacts with molecules containing free sulfhydryl groups. Likewise, when glutathione was depleted in K562 cells, by buthionine sulfoximine, high concentrations of bethoxazin were able to inhibit the formation of covalent adducts between sulfhydryl biomolecules and ThioGlo-1. The growth inhibition assay (MTS) was used to investigate the effect of continuous bethoxazin treatment versus wash out in K562 cells. The MTS assay revealed a reduction in the potency of bethoxazin due to the wash out effect, suggesting that the growth inhibition effects of bethoxazin are likely not due to glutathione depletion. A two-colour flow cytometry analysis of bethoxazin treated K562 cells for eight hours demonstrated that bethoxazin provokes necrosis induced cell death in K562 cells. Taken together, these experimental results demonstrate that the reaction of bethoxazin with proteins containing an accessible sulfhydryl group is more likely to be the mechanism of action of the cell growth inhibition effects rather than glutathione depletion.

Bethoxazin

Arginine-Rich Ionic Complementary Peptides and Their Drug Delivery Potential

Wan, Zizhen

12 August 2013

Ellipticine (EPT), a natural plant polyphenolic compound, has long been known for its significant anticancer and anti-HIV activities. Recent study on its photophysical properties has revealed that ellipticine has three molecular states: protonated, neutral and crystalline. Further in vitro cytotoxicity tests indicated that protonated ellipticine exhibited much higher anticancer activity than the other two states. To maximize drug therapeutic effect, a small library of ariginine-rich ionic complementary peptides derived from EAK, including EAR8-II, EAR8-a, ELR8-a, and EAR16-II, were investigated as a potential carrier to deliver prescribed protonated ellipticine for treatment of cancer. Fluorescence study demonstrated that all four peptides were able to solubilize and stabilize protonated ellipticine in aqueous solution at 5:1 mass ratio of peptide-to-ellipticine (0.5: 0.1 mg/mL) even upon 4000 times dilution. Physicochemical characteristics of peptides self-assemblies and peptide-ellipticine complexes such as particle size, surface charge, secondary structure and morphology were determined by dynamic light scattering (DLS), zeta potential, circular dichroism (CD) , atomic force microscopy (AFM) and transmission electron microscopy (TEM), respectively. Then the ellipticine maximum suspension was determined by ellipticine UV-absorption. With the help of the peptides and mechanical stirring overtime, up to 100% ellipticine could be uptaken and stabilized in the solution as protonated ellipticine. In vitro cytotoxicity tests indicated that the peptides were demonstrating significant biocompatibility without affecting the survival of two cancer cell lines, human lung carcinoma cell line A549 and breast cancer cell line MCF-7, whereas the complexes with protonated ellipticine were found to show great anticancer activity to the two cancer cell lines. The IC50 values were obtained for each of four different peptide-ellipticine complexes ranged from 0.36±0.12 to 18.90±0.46 μM. It is worth noting that the IC50 value of EAR16-ellipticine complex to MCF-7 was over 50 times higher than that one to A549, which presented that EAR16-ellipticine complex has a selective targeting activity to A549, with the lowest IC50 value of 0.36±0.12 μM among all four complexes. Such a result indicated that this library of novel arginine-rich ionic complementary peptides had a great potential to encapsulate prescribed protonated ellipticine and exhibited an excellent anticancer activity upon serial dilution in aqueous solution. Overall, the charge distribution and increased hydrophobicity of the short (8 amino acids length) peptides seemed not to affect the complex formation and its therapeutic efficacy in vitro; however, the increase in length of the peptides significantly altered the nanostructure of peptides and its complexation with ellipticine, increased the therapeutic efficacy of EAR16-EPT to A549. This work provides essential information for peptide sequence design in the development of self-assembling peptide-based delivery of hydrophobic anticancer drugs.

anticancer drug delivery