Affiliations of authors: G. Pagnan, F. Pastorino, L. Raffaghello, P. G. Montaldo, M. Ponzoni, Laboratory of Oncology, G. Gaslini Children's Hospital, Genoa, Italy; D. D. Stuart, T. M. Allen, Department of Pharmacology, University of Alberta, Edmonton, Canada; B. Calabretta, Kimmel Cancer Center, Thomas Jefferson University, Philadelphia, PA.
Correspondence to: Mirco Ponzoni, Ph.D., Laboratory of Oncology, G. Gaslini Children's Hospital, Largo G. Gaslini 5, 16148, Genoa, Italy (e-mail: mircoponzoni{at}ospedale-gaslini.ge.it).
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ABSTRACT |
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INTRODUCTION |
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In recent years, antisense oligodeoxynucleotides (asODNs) have shown efficacy in the selective inhibition of gene expression (10-13), but therapeutic applications of asODNs are limited by their low physiologic stability, unfavorable pharmacokinetics, low cellular uptake, and lack of tissue specificity. Instability has been largely overcome by employing backbone-modified oligodeoxynucleotides, such as phosphorothioate oligodeoxynucleotides (14). These analogues are more resistant to nucleases (10,14,15), but their animal pharmacokinetics and cytotoxicity appear relatively non-sequence specific. For example, the same morphologic and functional abnormalities (mainly involving the spleen, liver, and kidneys) were observed in animals treated with several oligodeoxynucleotides of different sequences, likely as a result of their accumulation in these organs (16-18).
The problem of low cellular uptake of asODNs has also been difficult to overcome. Endogenous uptake pathways have insufficient capacity to deliver the quantities of asODNs required to suppress gene expression (14,19,20). Forming complexes between asODNs and cationic liposomes (21,22) or polylysine (23) has enhanced intracellular delivery, but such complexes have disadvantages for in vivo applications. Cationic lipid complexes, for example, are rapidly cleared by the reticuloendothelial system and can be nonspecifically cytotoxic (24). Liposomes sterically stabilized with polyethylene glycol derivatives have circulation half-lives of approximately 12 hours and good stability in the presence of plasma, and they have recently been shown to facilitate delivery of asODNs in vivo (25,26). Sterically stabilized immunoliposomes, which have cell surface-directed antibodies on their exteriors, have been recognized as efficient tools for delivery of drugs and diagnostic agents to specific kinds of cells (27).
Among the antigens found on malignant cells, the disialoganglioside GD2 is an attractive target for immunoliposomal therapy of tumors of neuroectodermal origin (28,29), since it is extensively expressed in these tumors (30,31) but is less common in nonmalignant tissue. We have previously used GD2-targeted, sterically stabilized immunoliposomes to deliver the apoptosis-inducing drug fenretinide to melanoma cells in vitro (32). In this study, we investigated whether GD2-targeted, sterically stabilized liposomes containing c-myb asODNs selectively delivered to neuroblastoma cells sufficient asODNs to reduce c-Myb protein expression and to inhibit cell growth.
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MATERIALS AND METHODS |
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Hydrogenated soy phosphatidylcholine (HSPC), cholesterol, 1,2-distearoylglycero-3-phosphatidylethanolamine-N-polyethylene glycol-2000 (DSPE-PEG), and 1,2-dioleoyl-3-trimethylammonium propane (DOTAP) were from Avanti Polar Lipids, Inc. (Alabaster, AL). A derivative of DSPE-PEG with a maleimide group at the distal terminus of the polyethylene glycol chain (DSPE-PEG-MAL) was synthesized by Shearwater Polymers (Huntsville, AL). [3H]Cholesterol hexadecylether ([3H]CHE) was from Du Pont NEN (Boston, MA). All the other reagents of biochemical and molecular biology grade were obtained from Sigma Chemical Co. (St. Louis, MO).
Two different monoclonal antibodies (MAbs) directed against disialoganglioside GD2 (anti-GD2s) were employed. In the first set of experiments, we used 14.G2a, a murine MAb of immunoglobulin (Ig) G2a isotype subclass, specific for the GD2 antigen, provided by R. A. Reisfeld (The Scripps Institute, La Jolla, CA) (33). To reduce the possibility of adverse reactions to murine antibodies, we used, in a second set of experiments, the chimeric human-mouse MAb ch14.18. This antibody was constructed by combining constant regions of human IgG molecules with variable regions of a GD2-specific murine MAb (29) and was provided by R. Handgretinger (University of Tubingen, Tubingen, Germany).
Oligodeoxynucleotides
Three 24-mer phosphorothioate oligodeoxynucleotides were prepared, purified, and dried under vacuum by Lynx Therapeutics, Inc. (Hayward, CA). Our asODN, which is referred to hereafter as myb-as, is complementary to codons 2-9 of human c-Myb messenger RNA (mRNA) and has the sequence 5'-TATGCTGTGCCCGGGTCTTCGGGC-3'. It is currently being used in phase II clinical studies, where it is known as LR-3001 (34) . A sense oligodeoxynucleotide (myb-s) (5'-GCCCGAAGACCCGGGCACAGCATA-3') and a scrambled sequence (5'-TCGCGGATGTCCGGGTCTGTCGCT-3') oligodeoxynucleotide were used as controls.
Liposome Preparation and Oligodeoxynucleotide Encapsulation
A 700-µg portion of a given oligodeoxynucleotide with a trace of 125I-labeled oligodeoxynucleotide (to allow us to estimate the percentage of oligodeoxynucleotide present at various stages of the procedure) was dissolved in 0.25 mL distilled deionized water. Next, 0.51 mL methanol and 0.25 mL CHCl3 containing 2.17 µmol DOTAP were added, and the mixture was gently vortex mixed to form a monophase. After a 30-minute incubation at room temperature, 0.25 mL distilled deionized water and 0.25 mL CHCl3 were added. After mixing and centrifugation (800g for 7 minutes at room temperature), the aqueous methanol layer was removed. Under these conditions, which were developed in pilot studies using 10 µg oligodeoxynucleotide and various amounts of DOTAP, 90%-95% of the oligodeoxynucleotide was recovered in the organic phase. The resulting oligodeoxynucleotide-to-lipid mole ratio is 1 : 24, and a positive-to-negative charge ratio of 1 : 1 is obtained.
Following the extraction, 4.3 µmol cholesterol and appropriate amounts of HSPC, DSPE-PEG, or DSPE-PEG-MAL to give cholesterol-to-phospholipid mole ratios of 1 : 2 were added to the organic phase. Next, 0.2 mL distilled deionized water was added, and the mixture was vortex mixed and then emulsified by sonication for 2 minutes. The organic phase was evaporated with the use of a rotary evaporator (Buchi, Flawil, Switzerland). Liposomes, which form as the organic phase evaporates, were freeze-thawed in liquid nitrogen 10 times and then reduced in size to approximately 100 nm by extrusion six times through 200-nm and five times through 100-nm polycarbonate membranes (Avestin, Inc., Ottawa, ON, Canada) in a Liposofast extruder (Avestin, Inc.), as previously described (32,35). Liposomes prepared in this manner are called coated cationic liposomes (CCLs) (26,27).
Coupling of Anti-GD2 MAbs to Liposomes
A previously described method (36), slightly modified by us (32), was used to covalently link MAbs to the maleimide terminus of
DSPE-PEG-MAL.
To activate the anti-GD2s for reactivity toward the maleimide, we utilized
2-iminothiolane
(Traut's reagent) to convert exposed amino groups on the antibody into free sulfhydryl
groups. A
20 : 1 mole ratio of 2-iminothiolane to MAb and 1 hour of incubation at room temperature with
occasional mixing gave optimal MAb activation. After separation of thiolated MAb from
iminothiolane,
with the use of Sephadex G-25 column chromatography, the MAb was slowly added to a 5-mL
test
tube containing the liposomes (with encapsulated oligodeoxynucleotides) and a small magnetic
stirring
bar. Optimal coupling was obtained with the use of a phospholipid-to-MAb mole ratio of
1500-2000 :
1. Oxygen was displaced by running a slow stream of nitrogen over the reaction mixture. The
tube was
capped and sealed with Teflon tape, and the reaction mixture was incubated overnight at room
temperature with continuous slow stirring. The resulting immunoliposomes were separated from
unreacted MAb by chromatography with the use of Sepharose CL-4B, sterilized by filtration
through
0.2-µm pore cellulose membranes (Millipore Corp., Bedford, MA), and stored at 4 °C.
Coupling of MAbs to liposomes was quantified by adding trace amounts of 125I-labeled
MAb to the coupling reaction with liposomes, followed by -counting (Cobra 5002;
Canberra
Packard, Meriden, CT).
Coated cationic liposomes with covalently attached anti-GD2 MAb and encapsulated myb-as are referred to as GD2-targeted liposomes and abbreviated aGD2-CCL-myb-as throughout this report. Those that lack the antibody are referred to as nontargeted liposomes, and the "aGD2" prefix is omitted from the abbreviation. Liposomes with encapsulated myb-s have "myb-s" as their suffix.
Cell Lines and Culture Conditions
To broadly cover the phenotypes exhibited by neuroblastoma cells in vitro, we used four GD2-positive human neuroblastoma cell lines: GI-LI-N, ACN, HTLA-230, and LAN-5 (32,37). Four GD2-negative cell lines, adherent cell lines A431 (human epidermoid carcinoma) and HeLa (human cervical carcinoma) and suspension cell lines Jurkat (human T cell) and HL-60 (human leukemia), were used in some experiments. All cell lines were maintained in the logarithmic phase of growth at 37 °C in 75-cm2 plastic culture flasks (Corning Inc., Corning, NY) in a 5% CO2-95% air humidified incubator. They were split, washed, counted, and replated in fresh complete medium (RPMI-1640 medium [Biochrom, Berlin, Germany], supplemented with 10% heat-inactivated fetal calf serum [Biochrom], 50 IU/mL sodium penicillin G, 50 µg/mL streptomycin sulfate, and 2 mM L-glutamine), as previously described (32,38). A 1 mM EDTA solution in Hanks' balanced salt solution (Flow Laboratories, Milan, Italy) was used to release adherent cell lines from the surface of the culture flasks.
Binding and Uptake of Liposomes
Neuroblastoma cells or control GD2-negative cells were incubated in complete medium for 2 hours at 37 °C with various concentrations of [3H]CHE-labeled liposomes with encapsulated myb-as. Cells were washed extensively, treated with trypsin, and lysed with 1 N NaOH prior to measurement of radioactivity. In competition experiments, a 50-fold excess of free MAb was added 30 minutes before addition of the liposomes. In some experiments, the chimeric human-mouse variant ch14.18 anti-GD2 MAb or the nonspecific isotype-matched antibody, code X 0943 (Dako Corp., Glostrup, Denmark), was coupled to myb-as-entrapping liposomes, as described above.
Oligodeoxynucleotide Release
Release of oligodeoxynucleotides from liposomes was measured by dialyzing the oligodeoxynucleotide-containing liposomes in 25% human plasma from healthy donors or in complete medium against a large volume of the same solvent at 37 °C, using dialysis tubing with a molecular mass cutoff of 100 000 daltons. The dialysis bag was sampled at intervals, and the radioactivity was measured.
Uptake of asODNs by Neuroblastoma Cells
For the uptake studies, 50 µg/mL free or liposome-encapsulated myb-as was added to each well of six-well culture plates (Corning, Bibby Sterilin, Ltd., Staffordshire, U.K.) containing 5 x 105 cells/well. After incubation at 37 °C for 2 hours, the medium was removed, and cells were washed twice with ice-cold 1% bovine serum albumin (BSA) in phosphate-buffered saline (PBS), pH 7.4. Cells were resuspended in Versene (Life Technologies, Inc. [GIBCO BRL], Gaithersburg, MD), washed again with BSA in PBS, and centrifuged at 300g for 5 minutes at 4 °C. The cell pellet was suspended in 0.5 M NaCl in 0.2 M acetic acid (pH 2.5) and held at 4 °C for 10 minutes to elute surface-bound oligodeoxynucleotides. Samples were centrifuged at 300g for 5 minutes at 4 °C. The pellet was resuspended at a volume of 100 µL and then frozen at -20 °C. For dot-blot analyses, 400 µL 12.5 mM EDTA in 0.5 M NaOH was added to each frozen sample, and the samples were boiled for 10 minutes. They were then blotted onto a nylon membrane (Amersham Life Science, Inc., Arlington Heights, IL) by use of a dot-blot or a slot-blot apparatus (Bio-Rad Laboratories, Richmond, CA). The membrane was washed with 0.4 M NaOH and with 2x standard saline citrate (i.e., 300 mM NaCl and 30 mM sodium citrate), dried in an oven at 80 °C for 1 hour, and then hybridized with a 32P-labeled probe complementary to myb-as, as outlined in the ExpressHyb protocol (Clontech Laboratories, Inc., Palo Alto, CA). Time-dependence studies were carried out in the same way, except that the time of incubation was varied. Competition experiments were carried out by addition of a 50-fold excess of free anti-GD2 MAb 30 minutes before the addition of aGD2-CCL-myb-as.
Inhibition of Cell Growth
GI-LI-N or HeLa cells were plated in T-25 culture flasks (Corning) and treated with free myb-as, nontargeted liposomes (CCL-myb-as), GD2-targeted liposomes (aGD2-CCL-myb-as), or control oligodeoxynucleotide sequences (free or encapsulated in targeted or nontargeted liposomes) at an initial concentration of 80 µg/mL. After 18, 36, and 72 hours, additional oligodeoxynucleotides (same formulations as were added initially) were added at a concentration of 40 µg/mL.
In some experiments, 100 µg/mL of the various oligodeoxynucleotide formulations was added to cells at the beginning of the experiment and every 2 days thereafter. Two hours after each addition, the cells were washed to remove unbound oligodeoxynucleotides and transferred to fresh complete medium.
All experiments were continued for 8 days; at 2-day intervals, the cells were detached with EDTA, stained with trypan blue dye, and counted microscopically.
Western Blot Analysis of c-Myb in Neuroblastoma Cells
GI-LI-N cells (5 x 105) were treated with free myb-as, CCL-myb-as, or aGD2-CCL-myb-as at an initial concentration of 100 µg/mL. After 18 and 36 hours, additional myb-as (same concentration and formulations as were used initially) was added. Two hours after each addition, the cells were washed and transferred to fresh complete myb-as-free medium. Control cells were untreated with any myb-as formulation, washed, and transferred in the same way as the experimental cells. At 12-hour intervals from the beginning of the experiment, cells were harvested and stored frozen at -80 °C for later analysis. Frozen cell samples were solubilized in lysis buffer (i.e., 0.01 M Tris-HCI [pH 7.5], 0.144 M NaCl, 0.5% Nonidet P-40, 0.5% sodium dodecyl sulfate [SDS], 0.1% aprotinin, 10 µg/mL leupeptin, and 2 mM phenylmethylsulfonyl fluoride) and sonicated. The protein content of the samples was quantified with the use of the BCA protein assay (Pierce Chemical Co., Rockford, IL). Forty-microgram samples of protein were subjected to 10% SDS-polyacrylamide gel electrophoresis, with the use of prestained molecular weight markers (Amersham International, Little Chalfont, Buckinghamshire, U.K.) run in parallel to aid in the localization of the 75-kd c-Myb or 64- to 67-kd c-Myc protein. (The latter protein was used to test for equivalence of protein gel loading and transfer to the nitrocellulose membranes and the specificity of the myb-as.) The resolved proteins were blotted onto nitrocellulose membranes, and an anti-human c-Myb MAb (clone UBI 05-175; Upstate Biotechnology, Lake Placid, NY) or an anti-c-Myc MAb (clone 9E10; Cambridge Research Biochemicals, London, U.K.) was used to localize the c-Myb or c-Myc polypeptides on the blots. Peroxidase-conjugated goat anti-mouse antibodies (Bio-Rad Laboratories) were used as secondary antibodies. Immune complexes (i.e., proteins of interest) were visualized with the use of an enhanced chemiluminescence system (Pierce Chemical Co.). The relative amount of transferable c-Myb protein in a given sample was quantified by densitometry of x-ray films and normalization by staining the blotted nitrocellulose membranes with Ponceau red to estimate the amount of protein loaded.
Statistics
Results are expressed as means ± 95% confidence intervals (CIs). All data derive from at least four independent experiments.
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RESULTS |
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In experiments for which data are not shown, we noted the following: 1) Liposomes prepared by our procedure are typically 70-120 nm in diameter, as observed by electron microscopy (35); 2) an average of 65% (95% CI = 50%-80%) of the anti-GD2 antibody was associated with liposomes (presumably covalently attached through thioether bonds), with an antibody density of 60-80 µg MAb/µmol phospholipid; 3) the efficiency of asODN trapping in liposomes was estimated to be 80%-90%; 4) during 2-4 hours of dialysis at 37 °C in 25% human plasma, 10%-20% of asODN was released, and these asODNs were probably associated with the liposomal exterior; 5) continued dialysis for up to 1 week produced no more free asODN; and 6) our dialyzed liposomes retained their ability to bind to GD2-expressing cells over these same time periods.
Binding of GD2-Targeted Immunoliposomes to GD2-Positive and GD2-Negative Cells
We studied the concentration dependence of aGD2-CCL-myb-as-binding
to GD2-positive (GI-LI-N and ACN) and GD2-negative
(HeLa and HL-60) cells by measuring uptake of phospholipid from
liposomes. Phospholipid uptake by GD2-positive neuroblastoma
cell lines increased with phospholipid (i.e., liposome) concentration,
showing subsaturation at 400 nmol phospholipid/mL (Fig.
1). Similar results were obtained with the use of
both mouse 14.G2a or its chimeric human-mouse variant ch14.18
anti-GD2 MAbs (data not shown). The same liposome preparation
without anti-GD2 MAb (CCL-myb-as) showed very low
phospholipid uptake with no evidence of saturation. Preincubation of
cells for 30 minutes with soluble anti-GD2 MAb, but not with
an unrelated MAb, almost completely blocked phospholipid uptake by
cells, suggesting that aGD2-CCL-myb-as binding occurred through
specific antigen-antibody recognition. Moreover, coupling to liposomes
of nonspecific isotype-matched antibody did not increase phospholipid
uptake by neuroblastoma cells (data not shown). Both
GD2-negative cell lines showed very low cell phospholipid
uptake in all cases examined (Fig. 1).
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Four GD2-positive neuroblastoma cell lines and four
GD2-negative unrelated tumor cell lines were incubated with
free or encapsulated myb-as, and uptake of the oligodeoxynucleotide was
measured by dot-blot analysis. Since there were no obvious differences
in the degree of uptake of liposome-encapsulated myb-as by the four
GD2-positive cell lines, only the data obtained with two
GD2-positive cell lines (GI-LI-N and ACN) and one
GD2-negative cell line (HeLa) are shown (Fig.
2). Fig. 2,
A, is an example of the dot-blot
analysis
of myb-as uptake. The amount of myb-as taken up by
GD2-positive cells treated with aGD2-CCL-myb-as (dots 7 and
8) was substantially greater than that taken up by cells treated with
free myb-as (dots 3 and 4) or CCL-myb-as (dots 5 and 6). By using
densitometry, we estimated that the uptake of myb-as into GI-LI-N and
ACN cells was fourfold to fivefold higher when they were incubated with
aGD2-CCL-myb-as than when they were incubated with an equal amount of
free myb-as or CCL-myb-as (Fig. 2,
B). Longer incubation led to an
approximately 10-fold greater uptake of myb-as from aGD2-CCL-myb-as,
relative to uptake of free myb-as. After 24 hours' incubation, uptake
from aGD2-CCL-myb-as relative to uptake from CCL-myb-as decreased to only
twofold (Fig. 2,
C). In a competition experiment, the uptake of
aGD2-CCL-myb-as was inhibited by a 50-fold excess of free anti-GD2 (Fig. 2,
B).
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To determ ine the effects of myb-as on neuroblastoma cell
proliferation, we treated GI-LI-N cells with free or
liposome-encapsulated myb-as, using a protocol previously shown to
inhibit neuroblastoma cell growth by asODNs (9). As expected,
free myb-as inhibited GI-LI-N cell proliferation up to 70%. Treatment
of cells with CCL-myb-as or aGD2-CCL-myb-as induced a more rapid and
stronger inhibition of neuroblastoma cell growth (Fig. 3,
A). Conversely, in GD2-negative HeLa cells,
myb-as, in all formulations, affected cell proliferation to a smaller
extent (Fig. 3,
B). To demonstrate the sequence specificity of these
effects, we also delivered myb-s into GI-LI-N and HeLa cells. With the
use of formulations of the same types as those used with myb-as, myb-s
showed little or no growth inhibition (Fig. 3,
A and B).
Scrambled-sequence oligodeoxynucleotides also were ineffective (data
not shown).
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To investigate whether the enhanced cytotoxicity of aGD2-CCL-myb-as depends on specific recognition of cells by antibodies, competition studies were performed. Addition of a 50-fold excess of free anti-GD2 MAb to a culture of GI-LI-N cells that were growing in the presence of aGD2-CCL-myb-as caused a substantial reduction in the antiproliferative effect of aGD2-CCL-myb-as, while addition of an unrelated MAb had little effect (data not shown).
Effect of myb-as on c-Myb Expression in Neuroblastoma Cells
The expression of c-Myb protein in GI-LI-N cells treated with free
myb-as, CCL-myb-as, or aGD2-CCL-myb-as was analyzed by western blot
analysis (Fig. 4, A). Cells treated with free myb-as
or CCL-myb-as (by addition of 100 µg/mL inhibitor at 0, 18, and 36
hours followed, 2 hours later, by transfer to fresh inhibitor-free
complete medium) showed levels of protein expression similar to those
in the control (untreated) cells. In contrast, GI-LI-N cells treated
with the aGD2-CCL-myb-as showed a reduction in c-Myb protein levels of
about 70% in comparison with control cells. Free or liposome-entrapped
sense or scrambled analogues of myb-as did not affect c-Myb protein
expression (data not shown). The time dependence of this effect is
shown in Fig. 4,
B. To examine the specificity of protein repression by
myb-as, the effect of aGD2-CCL-myb-as on the expression of c-Myc
protein was determined. As expected, there was no repression of c-Myc
expression by aGD2-CCL-myb-as (Fig. 4,
C).
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DISCUSSION |
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Neuroblastoma is a pediatric neuroectoderm-derived tumor that often presents at an advanced stage and is characterized by a very poor prognosis. Despite development of very aggressive multimodal therapeutic approaches, the long-term survival of patients with neuroblastomas has not improved substantially over the last two decades (1,2). Additional therapeutic strategies are continuously being explored for their clinical potential as alternative or adjuvant treatment.
asODNs are being investigated as possible therapeutic agents that take direct advantage of molecular complementarity (10,17,18) to inhibit gene expression in a specific manner. The antisense approach uses a short oligodeoxynucleotide designed to bind to a target mRNA transcript through Watson-Crick base-pairing to form an asODN-RNA heteroduplex that inhibits gene expression.
While this conceptually simple, straightforward, and rational approach to novel drug design is attractive for the treatment of cancers and other human diseases (10,40), using it therapeutically to reduce or to eliminate expression of gene products important for the growth of neuroblastoma cells is much more complex for several reasons. These include the need to deliver asODNs selectively to specific areas of the body in order to maximize their action and to minimize their side effects (41), instability, and impermeability. A previously developed therapeutic strategy that addresses many of these potential problems uses liposomes as carriers for asODNs (42).
Here, we have described a system in which asODNs are encapsulated within small (about 100 nm) liposomes that have high trapping efficiencies (up to 90% of added oligodeoxynucleotide is stably associated with lipids) and bear covalently attached MAbs specific for the GD2 antigen on their exterior. The rationale for this approach is the extensive expression of GD2 on neuroblastoma cells in comparison to its limited presence on normal tissues, such as the peripheral nervous system and the cerebellum (28-31).
We have compared the cellular uptakes of free asODN, asODN encapsulated in GD2-targeted liposomes, and asODN encapsulated in nontargeted liposomes. Encapsulation of asODN in GD2-targeted liposomes was found to promote a fourfold to 10-fold increase in cellular uptake of asODNs when compared with the free oligodeoxynucleotide. The increase in uptake relative to CCL-myb-as approaches 10-fold at 6 hours' incubation time, but the relative size of the increase diminishes with time, to only twofold at 24 hours. Uptake was cell type specific: Of the cell types we examined, only those that express GD2 antigens took up more asODN from receptor-targeted liposomes than from nontargeted liposomes. That the uptake of asODN by neuroblastoma cells could be competitively inhibited by excess free anti-GD2 MAb is consistent with the hypothesis that intracellular delivery of asODN from GD2-targeted liposomes is mediated by GD2 molecules in the plasma membrane. Similar findings have been reported for the folate receptor (13,43).
Although we did not perform fractionation assays to assess the subcellular localization of immunoliposome-delivered asODN, we can conclude that it was not bound to the plasma membrane, since acetic acid was used to elute surface-bound asODN in our studies of asODN uptake. Because aGD2-CCL-myb-as was able to inhibit cell growth and to suppress c-Myb expression, we conclude that myb-as was delivered intracellularly in functionally active form. Since it has been shown that 14.G2a MAb was internalized by melanoma cells, even when conjugated to ricin A-chain (44), these findings suggest that, in our experimental model system, liposomes bind to the cell surface and are then internalized via a receptor-dependent endocytic pathway. This conclusion agrees with previous reports (13,45) that showed that endocytosis of immunoliposomes leads to nondestructive release of much of the internalized material into the cytosol, and it confirms the importance of internalizing receptors (27,36).
One of the most attractive features of antisense-based inhibitors is the potential for great specificity of their inhibitory effects (40). Demonstrating such specificity is usually considered to be the most important criterion for concluding that a true antisense mechanism explains the biologic effects of a particular oligodeoxynucleotide. For this reason, we have examined the specificity of inhibition of c-Myb expression and tumor growth by LR-3001, an oligodeoxynucleotide complementary to codons 2-9 of human c-Myb mRNA, and have demonstrated that the effects of this oligodeoxynucleotide are specific, as measured by a number of parameters. Scrambled and sense analogues of LR-3001 had no effect on c-Myb protein expression or on neuroblastoma growth in cell culture. LR-3001 inhibits c-Myb protein expression but does not affect the expression of c-Myc, a related transcription factor with a similar half-life (46). These findings suggest that the inhibitory effects of LR-3001 on c-Myb expression and its biologic consequences occur through an antisense mechanism.
Our results illustrate that encapsulation of asODN in GD2-targeted liposomes can protect nontargeted cells from a potentially toxic molecule while simultaneously enhancing the molecule's toxicity toward a targeted cell population. One cannot, however, expect that even a carefully targeted liposome will end up only at the intended tumor site; a portion of the dose could accumulate at other bodily locations with potentially toxic consequences. In future in vivo studies, the toxicity of aGD2-CCL-myb-as at nontargeted sites deserves attention.
The great advantages of liposome-encapsulated cytotoxic agents over free molecules have been unquestionably demonstrated in several animal models of cancer (47-50), mainly against small primary and micrometastatic solid tumors (36,51). Thus, the use of myb-as, encapsulated into GD2-targeted liposomes, may hold promise for the treatment of neuroblastoma in the minimal residual disease setting. Moreover, the great selectivity of aGD2-CCL-myb-as for GD2-positive cells suggests exploring using it to purge contaminating neuroblastoma cells from bone marrow before reinfusion into patients undergoing autologous bone marrow transplantation (52), possibly in combination with CD34+ cell selection.
Finally, the fact that many melanoma specimens have altered expression of c-Myb, coupled with the previously demonstrated inhibition of melanoma growth by c-myb asODNs, suggests that there may be a potential role for c-myb antisense therapy in the treatment of this tumor (53). Thus, immunotargeting of liposomes to neuroectoderm-derived tumor cells may provide an effective strategy for tumor site-selective delivery of drugs with broad therapeutic applications.
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NOTES |
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We thank R. A. Reisfeld and R. Handgretinger for furnishing us with 14.G2a and ch14.18 antibodies; G. Zon for providing us with LR-3001; C. Brignole and P. Bocca for expert technical assistance; E. Campochiaro for editing; and R. A. Reisfeld, L. Varesio, V. Corrias, and V. Pistoia for helpful discussions.
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Manuscript received June 22, 1999; revised November 18, 1999; accepted December 1, 1999.
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