Liposome-mediated delivery of ribosome inactivating proteins to cells in vitro

Natural and Designed Toxins for Precise Therapy: Modern Approaches in Experimental Oncology

Cancer cells frequently overexpress specific surface receptors providing tumor growth and survival which can be used for precise therapy. Targeting cancer cell receptors with protein toxins is an attractive approach widely used in contemporary experimental oncology and preclinical studies. Methods of targeted delivery of toxins to cancer cells, different drug carriers based on nanosized materials (liposomes, nanoparticles, polymers), the most promising designed light-activated toxins, as well as mechanisms of the cytotoxic action of the main natural toxins used in modern experimental oncology, are discussed in this review. The prospects of the combined therapy of tumors based on multimodal nanostructures are also discussed.

Nanopharmaceuticals and nanomedicines currently on the market: challenges and opportunities

There has been a revolution in nanotechnology and nanomedicine. Since 1980, there has been a remarkable increase in approved nano-based pharmaceutical products. These novel nano-based systems can either be therapeutic agents themselves, or else act as vehicles to carry different active pharmaceutical agents into specific parts of the body. Currently marketed nanostructures include nanocrystals, liposomes and lipid nanoparticles, PEGylated polymeric nanodrugs, other polymers, protein-based nanoparticles and metal-based nanoparticles. A range of issues must be addressed in the development of these nanostructures. Ethics, market size, possibility of market failure, costs and commercial development, are some topics which are on the table to be discussed. After passing all the ethical and biological assessments, and satisfying the investors as to future profitability, only a handful of these nanoformulations, successfully obtained marketing approval. We survey the range of nanomedicines that have received regulatory approval and are marketed. We discuss ethics, costs, commercial development and possible market failure. We estimate the global nanomedicine market size and future growth. Our goal is to summarize the different approved nanoformulations on the market, and briefly cover the challenges and future outlook.

Synergistic antitumor activity from two-stage delivery of targeted toxins and endosome-disrupting nanoparticles

Plant-derived Type I toxins are candidate anticancer therapeutics requiring cytosolic delivery into tumor cells. We tested a concept for two-stage delivery, whereby tumor cells precoated with an antibody-targeted gelonin toxin were killed by exposure to endosome-disrupting polymer nanoparticles. Co-internalization of particles and tumor cell-bound gelonin led to cytosolic delivery and >50-fold enhancement of toxin efficacy. This approach allows the extreme potency of gelonin to be focused on tumors with significantly reduced potential for off-target toxicity.

Methodology and experimental design for the study of liposome-dependent drugs

This chapter describes the concept of liposome-dependent drugs and the rationale for using them. Subsequently, procedures for studying and identifying liposome-dependent drugs are given. The first procedure described is a simple endpoint assay, and methods are given for both adherent and nonadherent cells. To establish in such a system that a drug is liposome dependent, it is necessary to demonstrate an IC(50) for the encapsulated drug that is less than that of the free drug, preferably with continuous exposure of the cells to drug. Subsequently, a second procedure is described, which is a more rigorous approach able to identify liposome dependency for a drug that is less effective in a carrier system than it is in the free form. This procedure is a multicompartment growth inhibition assay, wherein two cell populations are separated by a semipermeable membrane, through which free drug but not the liposomal carrier system may diffuse. The first population is adherent and is directly exposed to the liposomal or free drug. The second cell population is nonadherent and is exposed only to the drug that diffuses through the membrane. In addition to the methodology, experimental design is discussed and also the calculations needed to determine percent leakage, percent processing, percent metabolism, and the delivery factor, a parameter equivalent to a therapeutic index in an in vivo study.

Condensation properties of vesicles formed from an amphiphilic N-phosphorylamino acid

Stable unilamellar vesicles were formed in water under appropriate pH from dispersions of N-(O,O-di-n-hexadecyl)phosphorylalanine, an amphiphilic N-phosphorylamino acid. We found that condensation occurred in the vesicle solution after incubated at 40 degrees C, which may contribute to the stability of the vesicular system. Dipeptide derivative in the vesicle solution was identified by electrospray ionization mass spectrometry (ESI-MS), which suggests the peptide formation without any coupling reagents. Hydrogen bond and electrostatic interactions play important roles in the process of vesicle formation, while the suitable orientation and packing of the amphiphilic molecules at the vesicle/water interface together with certain conformational freedom in the vesicular bilayer are considered to be most favorable for the condensation in ordered systems as vesicles.

Organized Assemblies in Bolaamphiphile/Oppositely Charged Conventional Surfactant Mixed Systems

Five ionic bolaamphiphiles were synthesized and the aggregation behavior of bola single systems and bola/oppositely charged conventional surfactant mixed systems was studied. Small spherical vesicles were formed in all these mixed systems revealed by transmission electron microscopy (TEM). Variation of the structure of the hydrophobic chain of bolaamphiphiles has great influences on the vesicle formation ability. Vesicles were also found in the single system of a carboxylate bolaamphiphile, which was attributed to the hydrolysis of the bolaamphiphile. The results of FT-IR and X-ray diffraction (XRD) showed that bolaamphiphiles spanned through the vesicle membranes in these mixed systems. Super thermostability of the vesicles in this kind of mixed system was also investigated.

Tumor cell killing enabled by listeriolysin O-liposome-mediated delivery of the protein toxin gelonin

Gelonin is a type I plant toxin that has potential as an effective anti-tumor agent by virtue of its enzymatic capacity to inactivate ribosomes and arrest protein synthesis, thereby effectively limiting the growth of cancer cells. Being a hydrophilic macromolecule, however, gelonin has limited access to its target subcellular compartment, the cytosol; it is effectively plasma membrane-impermeant and subject to rapid degradation within endosomes and lysosomes upon cellular uptake as it lacks the membrane-translocating capability that is typically provided by a disulfide-linked B polypeptide found in the type II toxins (e.g. ricin). These inherent characteristics generate the need for the development of a specialized cytosolic delivery strategy for gelonin as an effective anti-tumor therapeutic agent. Here we describe an efficient means of delivering gelonin to the cytosol of B16 melanoma cells. Gelonin was co-encapsulated inside pH-sensitive liposomes with listeriolysin O, the pore-forming protein that mediates escape of the intracellular pathogen Listeria monocytogenes from the endosome into the cytosol. In in vitro experiments, co-encapsulated listeriolysin O enabled liposomal gelonin-mediated B16 cell killing with a gelonin IC50 of approximately 0.1 nM with an extreme efficiency requiring an incubation time of only 1 h. By contrast, cells treated with equivalent concentrations of unencapsulated gelonin or gelonin encapsulated alone in pH-sensitive liposomes exhibited no detectable cytotoxicity. Moreover, treatment by direct intratumor injection into subcutaneous solid tumors of B16 melanoma in a mouse model showed that pH-sensitive liposomes containing both listeriolysin O and gelonin were more effective than control formulations in curtailing tumor growth rates.

Antiproliferative effect and apoptotic response in vitro of human melanoma cells to liposomes containing the ribosome-inactivating protein luffin

The present study describes the liposome-mediated delivery of the type 1 ribosome-inactivating protein luffin to human melanoma cells in vitro. Luffin from Luffa cylindrica seeds has been successfully incorporated into lecithin/cholesterol and lecithin/cholesterol/dicetylphosphate negatively charged liposomes. The exposure of melanoma cells to the two types of liposomes resulted in the inhibition of protein synthesis and cell growth; apoptotic cell death was verified by means of TUNEL reaction and quantitation of cytosolic oligonucleosome-bound DNA. The toxicity of encapsulated luffin varied with the lipid composition of the vesicles; the strongest effect was observed with lecithin/cholesterol liposomes. These results identify liposome-incorporated luffin as a possible alternative to immunotoxins for the treatment of human melanoma in situ.

Efficiency of cytoplasmic delivery by pH-sensitive liposomes to cells in culture

The intracellular processing of pH-sensitive liposomes composed of cholesterylhemisuccinate (CHEMS) and dioleoylphosphatidylethanolamine (DOPE) by eukaryotic cell lines has been compared to non-pH-sensitive liposomes made of CHEMS and dioleoylphosphatidylcholine (DOPC). The pH-sensitive liposomes can deliver encapsulated fluorescent molecules [calcein, fluoresceinated dextran, fluoresceinated polypeptide, and diphtheria toxin A chain (DTA)] into the cytoplasm. Cytoplasmic delivery can be blocked in the presence of ammonium chloride or EDTA, indicating that the process requires a low-pH environment and the presence of divalent cations. Inhibition of cellular protein synthesis by DTA delivery from the pH-sensitive liposome is orders of magnitude greater than from the non-pH-sensitive liposome composition. The delivery of DTA into the cytoplasm by pH-sensitive liposomes is at least 0.01% of cell-associated liposomal DTA. There is no significant difference in the degradation rate of bovine serum albumin (BSA) or the rate of acidification of pH-sensitive dye, 8-hydroxy-1,3,6-pyrene-trisulfonate (HPTS), when delivered to cells in pH-sensitive and non-pH-sensitive liposomes. Thus the efficiency of cytoplasmic delivery is less than 10% of the cell-associated liposome contents, which is the smallest difference that can be detected by these two assays. Based upon the various assays used to measure liposome content disposition in the cell, we conclude that the efficiency of cytoplasmic delivery by the CHEMS/DOPE liposomes is greater than 0.01% and less than 10% of the cell-associated liposomal contents.

Imaging liposomes at electron microscopic level: encapsulated colloidal iron as an electrondense marker for liposome-cell interactions

Colloidal iron was encapsulated into liposomes prepared by different methods to provide an electrondense marker for easy identification of liposomes in cell and tissue culture. Stable colloidal iron solution can be prepared at virtually any concentration. The diameters of more than 75 per cent of the iron particles measured between 1 and 5 nm. Liposomes with a distinct electrondense core were evident at a colloidal iron solution concentration of 0.6 g/l. The colloidal iron labelled liposomes were easily identified in cells after incubation by routine electron microscopic procedures. Liposomes could be found in lysosomes or endosomes of human M21 melanoma cells. Intact, as well as partially degraded liposomes were present after two hours of incubation.

Lysis of natural killer-sensitive and -resistant tumor cells by natural killer cytotoxic factors (NKCF)-containing liposomes

The lethal hit stage in NK cell-mediated lysis requires a complex series of events involving the release of NKCF, subsequent binding of these factors to the target cell, and susceptibility of the target cell to lysis by NKCF. Binding of NKCF alone is not sufficient because a number of tumor cells are able to bind NKCF without being lysed, suggesting the need for an additional processing step active on susceptible target cells. In the present study, we show that the interaction with liposome-incorporated NKCF renders NK resistant target cells sensitive to NKCF-mediated lysis. These results suggest that NKCF may mediate their cytotoxic effects through internalization of these factors into the cytosol.

Ribosome-inactivating proteins up to date

Ribosome-inactivating proteins (RIPs) from plants inactivate eukaryotic ribosomes, as far as studied by rendering their 60 S subunit unable to bind elongation factor 2. These proteins seem widely distributed and possibly ubiquitous in plants. They are either type 1, those consisting of a single polypeptide chain, or type 2 (ricin and related toxins), those consisting of two chains, one of which is a galactose-binding lectin. The literature on RIPs from 1982 has been reviewed with respect to the chemical and biological properties of RIPs, their use for the preparation of immunotoxins and new perspectives.

Cytolytic activity of liposomes containing stearylamine

In order to develop the cytotoxic liposome, the cytolytic effect of polycationic liposome was examined. Upon incubation of the stearylamine-containing liposome (stearylamine-liposome) with rabbit erythrocyte, a significant extent of hemolysis was observed. Hemolytic activity of the liposome depends on the amount of stearylamine in the liposome membrane. The plots of the initial rate of hemolysis versus the concentration of stearylamine-liposome showed a sigmoidal curve, suggesting that stearylamine-liposomes act cooperatively on the erythrocyte membrane. Hemolytic activity of stearylamine-liposome was markedly influenced by the composition of hydrocarbon chains of the phospholipids in the liposome membrane, suggesting that the membrane fluidity of stearylamine-liposome is important to evoke the hemolysis. Since the liposomes containing acidic phospholipids inhibited markedly the stearylamine-liposome-caused hemolysis, it is likely that the primary target of stearylamine-liposome is the negatively charged component(s) such as acidic phospholipids on the erythrocyte membrane. Furthermore, stearylamine-liposome induced the release of the intravesicular contents from the liposome made of acidic phospholipids but not from the liposome made of phosphatidylcholine only. These results suggest that stearylamine-liposome interacted with the negative charges of the erythrocyte membrane and eventually damaged the cell. Erythrocytes from rabbit, horse and guinea pig are highly susceptible to stearylamine-liposome but those from man, sheep, cow and chicken are less so.

The effects of liposome size and surface charge on liposome-mediated delivery of methotrexate-gamma-aspartate to cells in vitro

We have studied the liposome-mediated delivery of methotrexate-gamma-aspartate to five cell lines. The sensitivity of the cells to encapsulated drug varies widely in accordance with their ability to take up the liposomes. CV1-P cells can be 150-times more sensitive to encapsulated methotrexate-gamma-aspartate than to free drug, while AKR/J SL2 cells are only twice as sensitive to the encapsulated drug. Negatively-charged liposomes are much more efficient for delivery than are neutral liposomes, and cholesterol is an essential component of the liposome membrane for optimal drug delivery. The optimal liposome size for drug delivery is 0.1 micron, although the amount of cell-associated lipid is the same for all liposome sizes. The effect of the encapsulated drug is inhibited by NH4Cl, suggesting an endocytic mechanism for delivery. The potency of the encapsulated drug is not affected by wide variations in the drug: lipid ratio.

Quantitation of the delivery of liposome contents into plant protoplasts

A procedure for the quantitation of the delivery of liposome contents into Catharanthus roseus protoplasts has been developed. The method is based on the uptake of liposome encapsulated methylumbelliferyl beta-D-glucoside and its enzymatic hydrolysis to yield fluorescent methylumbelliferone. Since the free glucoside is not taken up by the protoplasts to a significant extent, the delivery of material in the nanomole range can be measured with ease.

Liposomes as a means to introduce fragment A of diphtheria toxin into cells

The incorporation of fragment A of diphtheria toxin into liposomes is described. The intracellular delivery of the entrapped toxin, as evidenced by the inhibition of protein synthesis by a human lymphoblastoid cell line could be demonstrated with liposomes that contained phosphatidylethanolamine or phosphatidylserine in addition to phosphatidylcholine and cholesterol. Free fragment A, either alone or added to empty liposomes of any composition, did not affect protein synthesis, even when present in considerably higher concentrations than the liposome-entrapped form.

Cytotoxicity acquired by ribosome-inactivating proteins carried by reconstituted Sendai virus envelopes

Association of the ribosome-inactivating proteins (RIPs): pokeweed antiviral protein (PAP), gelonin, Momordica charantia inhibitor (MCI), with reconstituted Sendai virus envelopes (RSVE) was obtained without detectable loss of activities either of RIPs or of viral envelope glycoproteins. RIPs are inactive towards intact cells, but, once encapsulated in RSVE, they become cytotoxic. The concentration of RSVE-associated PAP, which causes 50% inhibition of protein synthesis by Friend erythroleukemic cells, is 0.5 ng/ml. Substances capable to inhibit the viral activities block the acquired cytotoxicity of RIPs associated to RSVE.