Antisense Oligodeoxynucleotide Technology: Potential Use for the
Treatment of Malignant Brain Tumors
Herbert H. Engelhard, MD, PhD
The use of antisense oligodeoxynucleotides as a possible treatment for
patients with brain tumors is promising due to their specificity, ease of production, and
lack of adverse effects.
Background: Antisense oligodeoxynucleotides (ODNs) have been proposed as a
new therapy for patients with cancer, including malignant brain tumors. Antisense
ODNs are taken up by tumor cells and selectively block gene expression. Use of ODNs
for brain tumors is attractive due to their theoretical specificity, relative ease of
production and, to date, paucity of reported adverse effects. This article presents
current information regarding antisense ODNs and their possible future use for the
treatment of brain tumors.
Methods: The available published experimental and clinical information
regarding antisense ODN treatment of glioblastoma cells and administration into the
central nervous system (CNS) was reviewed. Other clinically relevant information
pertaining to the molecular biology of antisense ODNs was also collected and summarized.
Results: Targets for antisense ODN therapy in malignant glioma cells have
included c-myc, c-myb, c-sis, c-erb B, CD44, p34cdc2, bFGF, PDGF, TGF-beta, IGF-1,
PKC-alpha tumor necrosis factor, urokinase, and S100beta protein. Few in vivo studies of
ODN treatment of brain tumors have yet been reported. Systemically administered ODNs
enter the brain only in extremely small quantities; therefore, microinfusion into the
brain has been recommended.
Conclusions: Antisense ODNs have been used successfully to block
glioblastoma gene expression in vitro and expression of multiple genes within the CNS of
experimental animals. Upcoming clinical trials will address the safety of antisense
ODN use against malignant brain tumors.
Introduction
The concept of antisense-mediated gene inhibition, first introduced
by Stephenson and Zamecnik1 in 1978, has now emerged as a potentially powerful
alternative or adjunct to conventional cancer chemotherapy.2-9 This is
particularly exciting in the case of malignant astrocytomas, where results with
traditional chemotherapy have been disappointing. The discovery that synthetic fragments
of DNA can inhibit the transcription and/or translation of selected genes in a
sequence-specific manner initially opened up a new mechanism for analyzing gene function,
then launched a new field of drug development in which early clinical trials are now
proceeding.4,10-13
Clinical applications for antisense ODNs have been envisioned in
many fields including oncology, vascular and genetic diseases, and the treatment of the
human immunodeficiency virus and other viral infections.7,12,14-19 The term
"antisense" refers to the fact that the nucleic acid synthesized is
complementary to the coding (ie, "sense") genetic sequence of the target gene.10
Antisense constructs hybridize in an antiparallel orientation to nascent mRNA through
Watson-Crick base-pairing.12 Theoretically, an oligomer 17 nucleotides in
length should find a unique target within the 3 x 109 base pairs of the human
genome.2,12,20
To date, two main antisense strategies have been employed:
transfection of cells with antisense cDNA and treatment of cells with the shorter
antisense oligodeoxynucleotides (ODNs). The former strategy has been successfully used in
vitro against glioblastoma cells with gene targets such as basic fibroblast growth
factor (bFGF),21 or protein kinase C isotype a (PKCa),22 and in
animal glioma models targeting insulin-like growth factor 1 (IGF-1)23 or
vascular endothelial growth factor (VEGF).24,25 The latter strategy has been
more widely used, however, and is the focus of this review. In comparison to the cDNA
approach, antisense ODNs are easier to synthesize and obviate the need for a viral vector
for delivery to cells.
In order to be useful therapeutically, an ODN must (1) exhibit
reasonable stability in the physiologic (or pathologic!) environment, (2) be taken up and
retained in adequate quantities by the target (here, neoplastic) cells, (3) specifically
bind target mRNA with high affinity, (4) have an acceptable therapeutic ratio, being free
of unwanted toxic and nonspecific side effects, and (5) be easily synthesized in
sufficient quantities to allow clinical use.3,10,26,27 Most of these criteria
have already been met by phosphorothioated ODNs (described below); yet, second-generation
ODNs are already under development.
ODN Modifications and Cellular Uptake
Unmodified ODNs are polyanions with a phosphodiester backbone (Fig
1A). They are rapidly degraded under physiologic conditions by single-stranded nucleases,
primarily 3'-exonucleases.3,26 Because of this, ODN modifications have been
designed to retard degradation. The phosphorothioate modification of the oligonucleotide
backbone (Fig 1B), in which a sulphur atom replaces one of the nonbridging oxygen atoms in
the phosphate group,3 produces ODNs that are relatively resistant to cellular
and serum nucleases. Phosphorothioated ODNs have been the type most commonly used in
investigations to date, including studies of malignant glioma.8,10,11,28-35
Another variation of the backbone produces the methylphosphonate modification (Fig 1C).36,37
Methylphosphonate ODNs have no net charge, which aids in preventing nuclease digestion but
also decreases water solubility.7,10 In considering access to the CNS, however,
the use of the more lipophilic methylphosphonates could be advantageous. The
phosphoramidate modification (Fig 1D) has more recently been described.6,38
Phosphoramidates may offer advantages over phosphorothioated ODNs, such as decreased
nonspecific binding to proteins.39
Cellular uptake of ODNs occurs by means of fluid-phase pinocytosis
and/or receptor-mediated endocytosis.20,40 Other modifications of ODN structure
have been designed to increase cellular uptake. Enhanced delivery of ODNs to cells has
been achieved by combining them with synthetic cationic lipids or by linking them to
hydrophobic moieties such as porphyrin or cholesterol.7,13,20,41 Enhancement of
receptor-mediated uptake has also been described, for example, by conjugating ODNs to a
polylysine complex with or without transferrin.6,26,42 The use of liposomes as
delivery vehicles has been used to increase cellular uptake and protect from extracellular
degradation.13,16,20,26,43 "Second generation" ODNs have now been
introduced, including the creation of chimeric molecules that have chemically modified
"wings" around a central phosphorothioated central "window."3
It is hoped that second generation ODNs will retain specificity, efficacy, and nuclease
resistance while avoiding potential nonspecific side effects.
Mechanisms of Antisense ODN Action
Although the mechanisms of antisense ODN action continue to be
elucidated, on a fundamental level, antisense ODNs bind the target mRNA template, thus
blocking successful translation of the corresponding protein.5,44,45
High-affinity binding can occur in the cytoplasm (to mRNA) and/or nucleus (to hnRNA) after
passage through nuclear pores. The formation of the DNA:RNA heteroduplex results in gene
inactivation either through steric blocking of the ribosome complex or by triggering mRNA
cleavage by RNase H.2,14,33 Cleavage is rapidly followed by further degradation
and is therefore an irreversible process.6,8,12,45,46 Antisense ODN constructs
also can interfere with transcription by a process called triple-helix formation (the
"antigene" strategy), in which the ODN binds to double-stranded DNA in the
nucleus.2,20,45,47-49 Genetic targets for this type of strategy, however, are
more limited since they must be pure polypurine tracts.10
Theoretically, antisense ODNs could also act by (1) hybridizing to
open DNA loops created by RNA polymerase or at intron-exon junctions, (2) interfering with
mRNA splicing or transport of mRNA from the nucleus to the cytoplasm, or (3) interfering
with translation through inhibition of the binding of initiation factors or assembly of
ribosomal subunits at the start codon, among other possibilities.2,20,33,45,48
Antisense agents called "ribozymes" have been designed that induce catalytic
cleavage of target RNA by the addition of a sequence that has natural self-splicing
activity.20,37,45 In carrying out the cleavage, the ribozyme itself is not
altered and thus is capable of continuing to cleave other molecules.20
Targets for Antisense ODNs in Malignant Brain Tumor Cells
Given the continued poor prognosis of patients with malignant brain
tumors, many investigators have suggested that ODN therapy might be useful.26,28,29,32,50-54
Reported target genes for antisense ODN therapy in malignant glioma cells (Table) have
included bFGF, c-myc, c-sis, c-erb B, c-myb, CD44, p34cdc2,
platelet-derived growth factor, transforming growth factor-beta, IGF-1, PKC-alpha, tumor
necrosis factor, urokinase, and the S100beta protein.26,28-30,35,47,49-52,55-61
In the studies using these target genes, mRNA and/or protein expression was successfully
down-regulated, often with corresponding decreases in tumor cell growth or other
neoplastic phenotype. Usually, the more specific part of the mRNA that is targeted is at
the 5' end of the transcript, spanning the translation initiation codon.7 The
number of additional potential targets for ODN therapy of glioma cells is extremely large,
including genes coding for other examples of (1) growth factors and their receptors, (2)
cellular proteases, kinases, and second messengers, (3) proto-oncogenes, and (4) factors
and proteins important in cell cycle control and apoptosis, to identify but a few
categories.
Targets for Antisense ODN Therapy of
Glioblastoma (In Vitro) |
| Targets |
Investigators |
| |
| Proto-oncogenes: |
| |
c-sis |
Nitta 199452 |
| |
c-erb B |
Okada 199449 |
| |
c-myc |
Chavany 1995,63 Broaddus 1997,32
Engelhard 199830 |
| |
c-myb |
Hall 199626 |
| |
| Growth Factors: |
| |
Basic fibroblast growth factor |
Morrison 1991,58 Murphy 1992,59 Behl
199350 |
| |
Platelet-derived growth factor |
Behl 199350 |
| |
Transforming growth factor beta |
Jachimczak 199635 |
| |
Insulin-like growth factor 1 |
Resnicoff 199451 |
| |
| Other: |
| |
Protein kinase C alpha |
Baltuch 1995,55 Yazaki 199653 |
| |
Urokinase |
Engelhard 1996,28 Engelhard 199830 |
| |
CD44 |
Merzak 199454 |
| |
p34cdc2 |
Mercer 199256 |
| |
Tumor necrosis factor |
Aggarwal 199647 |
| |
S100beta protein |
Selinfreund 1990,60 Van Eldik 199261 |
Non-antisense Effects of ODN Treatment
Nonspecific and "paradoxical" (ie, opposite than those
expected) effects of ODN treatment have been encountered even in the most simple in
vitro systems.16,28,30,35,46,62,63 Nonspecific effects may in some cases be
advantageous, such as inhibiting the migration of glioblastoma cells.30 The
mechanisms for the nonspecific effects of ODNs could be related to (1) the structure of
the ODN itself, (2) hybridization to DNA or mRNA other than the target sequence, with
subsequent RNase cleavage, (3) binding to proteins or other molecules, and/or (4) ODN
degradation products, which in themselves can affect cellular functions.2,3,6,8,16,17,20,30,45,64,65
Phosphorothioated ODNs have been shown to be inherently growth-inhibitory,66
particularly those having four adjacent guanosine bases.30,39,67
As polyanions, ODNs have been shown to nonspecifically bind proteins
such as bFGF, VEGF, PKC, and protein tyrosine receptors including the epidermal growth
factor receptor.8,12,39,68 Phosphorothioated ODNs have also been reported to
cause nonspecific induction of tumor necrosis factor,69 induction of Sp1
nuclear transcription factor binding activity,11,70 and inhibition of
transferrin receptor expression.71 Nonspecific effects of phosphorothioated
ODNs are usually encountered in the 20- to 50-µM range.10 Despite these
nonspecific interactions, reports of ODN-mediated cellular toxicity have been rare.72
ODN Pharmacokinetics and Delivery to the Brain
Studies of intravenous injection of unmodified (phosphodiester) ODNs
have shown that the plasma half-life is approximately five minutes.19,34 The
phosphorothioate modification produces a significant prolongation in plasma half-life to
30-60 minutes; steady-state plasma levels can be achieved with repeated daily intravenous
injections.13,19,31 Phosphorothioate ODNs bind to serum albumin and alpha2
macroglobulin and demonstrate two-phase pharmacokinetics.11,12,19,33
Regarding passage across the blood-brain barrier, most ODNs are negatively charged, and
the molecular weight of an ODN of 14 bases is approximately 5 kDa.10 Animal
studies of ODN biodistribution have shown that ODNs administered intravenously,
subcutaneously, or intraperitoneally accumulate primarily in the liver, kidney, and other
organs of the reticuloendothelial system, entering the brain only in minute quantities.7,11,19,31,67,73
Because of this, direct injection or osmotic minipump infusion into the CSF, brain
parenchyma, or intracerebral tumors has been employed.10,28,58,73-75 Fig 2
illustrates the cerebral distribution of fluorescein isothiocyanate (FITC)-labeled
phosphorothioate ODN after injection into the cisterna magna of a rat. Figs 3A-B show the
fluorescence of malignant glioma cells (rodent C6 brain tumor model) in which the tumor
was directly infused with FITC-labeled phosphorothioate ODNs.
Studies of ODNs administered into the ventricles of the rat have
shown that phosphodiester ODNs are rapidly degraded, whereas phosphorothioate ODNs are
resistant to degradation and are cleared in a manner consistent with bulk flow.75
Phosphorothioate ODNs given for a week in this manner did not show evidence of toxicity,
yet penetrated the brain extensively and were taken up by astrocytes.75 Other
investigators have confirmed the superiority of phosphorothioate ODNs for CNS
administration, the cellular uptake and biodistribution of intracranially administered
ODNs, and their apparent lack of adverse effects.28,76-79 Transcription of a
variety of different genes has been successfully blocked in nonneoplastic rat brain by
means of direct ODN infusion into different regions of the brain. These genes play roles
(as examples) in mediating traumatic brain injury, pain perception, thirst regulation,
blood pressure elevation, memory functions, behavior and/or motor control.80-98
Some of the effects were seen with the administration of just a single ODN dose.34
ODNs may be more stable within the CNS than in other bodily compartments.34 In
one report of a possible adverse effect, an ODN injected into rat brain was found to cause
an inflammatory response, with induction of interleukin-6 expression.99
Liposome structures have been used to enhance ODN delivery to the CNS.100
Potential Obstacles to Successful Clinical Use of ODNs in Oncology
In addition to the possible occurrence of nonspecific or even
paradoxical effects in the antisense ODN treatment of tumor cells (as outlined above),
other potential pitfalls to the clinical use of antisense ODNs certainly can be
envisioned. While a possible advantage in terms of targeting for some diseases,
accumulation of ODNs by the components of the reticuloendothelial system (when
administered systemically) has the potential for producing adverse effects. In animal
studies, elevation of liver enzymes, splenomegaly, immune stimulation, thrombocytopenia,
prolongation of the activated partial thromboplastin time, and/or liver failure have been
reported.4,8,12,34 Some of these effects were found to be dependent on ODN base
sequence, backbone modification, and/or dosage schedule and could be avoided.34
Even with acceptable toxicity, with adequate ODN entry into brain
tumor cells (across or by circumventing the blood-brain barrier), and with demonstrated
translation arrest of the target gene, successful treatment of malignant tumors is still
likely to be problematic. Multiple genes may be important in determining the survival,
proliferation, and invasiveness of cancer cells, and the expression of these genes may
change over time in what is conceived to be a multistep process of malignant
transformation.20 Malignant gliomas in particular are known to be highly
heterogeneous as a group and even within a given patient’s tumor. Individual
glioblastoma patients may express different sets of genes culminating in the malignant
phenotype; furthermore, expression of different sets could coexist within different cells
of the same tumor. Blocking one or more pathways to malignancy might simply result in the
activation of an alternative means to continue to proliferate and invade adjacent brain.
In Vivo Use of ODNs Against Cancer:
Preclinical Studies and Clinical Trials
Despite the theoretical obstacles to the successful use of antisense
ODN therapy for cancer, ODN-induced down-regulation of tumor genes including c-myc,
N-myc, c-myb, Ha-ras, c-raf, bcr-abl, PKC-alpha, PKA
and NF-kappaB, has been achieved in several different animal cancer models.2,7,8,11,13,34,53,101-103
Yazaki et al53 reported the use of a phosphorothioate ODN directed against
PKC-alpha that, when given intraperitoneally showed efficacy against U-87 (human
glioblastoma) cells grown subcutaneously and intracerebrally in mice.
Clinical trials with ODNs are now proceeding for several different
types of cancer as well as other diseases.8,12,13,34,104 Tumor genes that are
being targeted include c-myb, bcl-2, PKC-alpha, p53 and c-raf.12,34
The results of the first phase I trials of a phosphorothioated ODN targeting p53 mRNA have
been reported.8,104,105 No toxicity was observed in patients who received 0.05
to 0.2 mg/kg per hour ODN intravenously for 10 days. A phase I study for malignant brain
tumors currently underway involves the systemic administration of an anti-PKC-alpha ODN
(Isis/Ciba-Geigy), by the New Approaches to Brain Tumor Therapy Consortium based at The
Johns Hopkins University.
Conclusions
Impressive advances have been made in molecular techniques over the
past two decades. Such advances first led to the identification of potential targets for
gene-targeted therapy (such as proto-oncogenes, second messengers, and growth factor
receptors) and have now resulted in commercial production of molecules capable of
specifically binding to these targets and disrupting their activity. Antisense ODN
treatment of glioma cells can certainly be used to block gene expression in vitro;
early results with ODNs administered in animal brain tumor studies have also been
encouraging.28,29,53 As with almost any type of therapy, problems with the use
of antisense ODNs for treating brain tumors and other CNS diseases (some of which have
been discussed here) could be encountered. Potential difficulties related to the clinical
use of ODNs, however, do not seem insurmountable.7 Combination therapy with
different ODNs or the use of ODNs in conjunction with conventional chemotherapeutic agents
may be required to achieve therapeutic efficacy.20 Information pertaining to
potential adverse interactions between conventional therapeutic agents and antisense ODNs
is currently not available.
The idea of treating brain tumor patients with antisense ODNs
continues to be attractive due to their theoretical specificity,2,27,39,70
relative ease of production through automated synthesis,27,40 and paucity (to
date) of reported adverse effects.13,28,29,45,53,74 Even if toxic side effects
are found, their occurrence will have to be balanced with the severity of the disease
being treated.34 In the case of glioblastoma multiforme, if any efficacy of ODN
treatment is shown, significant side effects might still be acceptable. Given the
continued poor prognosis for patients with malignant brain tumors, preliminary results
from phase I studies are being anxiously awaited.
Appreciation is expressed to Ms Janeen Fitzpatrick for assistance with typing this
manuscript.
References
1. Stephenson ML, Zamecnik PC. Inhibition of Rous sarcoma viral RNA translation by a
specific oligodeoxyribonucleotide. Proc Natl Acad Sci U S A. 1978;75:285-288.
2. Hélène C. Control of oncogene expression by antisense nucleic acids. Eur J
Cancer. 1994;30A:1721-1726.
3. Altmann KH, Fabbro D, Dean NM, et al. Second-generation antisense oligonucleotides:
structure-activity relationships and the design of improved signal-transduction
inhibitors. Biochem Soc Trans. 1996;24:630-637.
4. Agrawal S. Antisense oligonucleotides: towards clinical trials. Tibitech.
1996;14:376-387.
5. Cohen JS. Oligonucleotides as therapeutic agents. Pharmacol Ther.
1991;52:211-225.
6. Milligan JF, Matteucci MD, Martin JC. Current concepts in antisense drug design. J
Med Chem. 1993;36:1923-1937.
7. Tonkinson JL, Stein CA. Antisense oligodeoxynucleotides as clinical therapeutic
agents. Cancer Invest. 1996;14:54-65.
8. Ma L, Calvo F. Recent status of the antisense oligonucleotide approaches in
oncology. Fundam Clin Pharmacol. 1996;10:97-115.
9. Sharma HW, Narayanan R. The therapeutic potential of antisense oligonucleotides. Bioessays.
1995;17:1055-1063.
10. Brysch W, Schlingensiepen KH. Design and application of antisense oligonucleotides
in cell culture, in vivo, and as therapeutic agents. Cell Mol Neurobiol.
1994;14:557-568.
11. Crooke ST, Bennett CF. Progress in antisense oligonucleotide therapeutics. Annu
Rev Pharmacol Toxicol. 1996;36:107-129.
12. Ho PT, Parkinson DR. Antisense oligonucleotides as therapeutics for malignant
diseases. Semin Oncol. 1997;24:187-202.
13. Szymkowski DE. Developing antisense oligonucleotides from the laboratory to
clinical trials. Drug Discovery Today. 1996;1:415-428.
14. Askari FK, McDonnell WM. Antisense-oligonucleotide therapy. N Engl J Med.
1996;334:316-318.
15. Calabretta B. Inhibition of proto-oncogene expression by antisense
oligodeoxynucleotides: biological and therapeutic implications. Cancer Res.
1991;51:4505-4510.
16. Tidd DM. Anticancer drug design using modified antisense oligonucleotides. In:
Murray JAH, ed. Antisense RNA and DNA. New York, NY: Wiley-Liss; 1992:227-240.
17. Wagner RW. Gene inhibition using antisense oligodeoxynucleotides. Nature.
1994;372:333-335.
18. Wickstrom E, ed. Prospects for Antisense Nucleic Acid Therapy of Cancer and AIDS.
New York, NY: Wiley-Liss; 1991.
19. Agrawal S, Temsamani J, Galbraith W, et al. Pharmacokinetics of antisense
oligonucleotides. Clin Pharmacokinet. 1995;28:7-16.
20. Warzocha K, Wotowiec D. Antisense strategy: biological utility and prospects in the
treatment of hematological malignancies. Leuk Lymphoma. 1997;24:267-281.
21. Redekop GJ, Naus CC. Transfection with bFGF sense and antisense cDNA resulting in
modification of malignant glioma growth. J Neurosurg.1995;82:83-90.
22. Ahmad S, Mineta T, Martuza RL, et al. Antisense expression of protein kinase C
alpha inhibits the growth and tumorigenicity of human glioblastoma cells. Neurosurgery.
1994;35:904-908.
23. Shevelev A, Burfeind P, Schulze E, et al. Potential triple helix-mediated
inhibition of IGF-I gene expression significantly reduces tumorigenicity of glioblastoma
in an animal model. Cancer Gene Ther. 1997;4:105-112.
24. Saleh M, Stacker SA, Wilks AF. Inhibition of growth of C6 glioma cells in vivo by
expression of antisense vascular endothelial growth factor sequence. Cancer Res.
1996;56:393-401.
25. Cheng SY, Huang HJ, Nagane M, et al. Suppression of glioblastoma angiogenicity and
tumorigenicity by inhibition of endogenous expression of vascular endothelial growth
factor. Proc Natl Acad Sci U S A. 1996;93:8502-8507.
26. Hall WA, Flores EP, Low WC. Antisense oligonucleotides for central nervous system
tumors. Neurosurgery. 1996;38:376-383.
27. Stein CA, Cheng YC. Antisense oligonucleotides as therapeutic agents: is the bullet
really magical? Science. 1993;261:1004-1012.
28. Engelhard H, Narang C, Homer R. Urokinase antisense oligodeoxynucleotides as a
novel therapeutic agent for malignant glioma: in vitro and in vivo studies
of uptake, effects and toxicity. Biochem Biophys Res Commun. 1996;227:400-405.
29. Engelhard HH, Rozental JM. Status of antisense oligodeoxynucleotides as a novel
treatment for malignant glioma. Int J Oncol. 1997;11(suppl):902.
30. Engelhard HH, Duncan HA, Kim S, et al. Paradoxical and nonspecific effects of
antisense treatment of human glioblastoma cells. 1998. In press.
31. Agrawal S, Temsamani J, Tang JY. Pharmacokinetics, biodistribution, and stability
of oligodeoxynucleotide phosphorothioates in mice. Proc Natl Acad Sci U S A.
1991;88:7595-7599.
32. Broaddus WC, Chen ZJ, Prabhu SS, et al. Antiproliferative effect of c-myc
antisense phosphorothioate oligodeoxynucleotides in malignant glioma cells. Neurosurgery.
1997;41:908-915.
33. Crooke ST. Progress in antisense therapeutics. Med Res Rev. 1996;16:319-344.
34. Akhtar S, Agrawal S. In vivo studies with antisense oligonucleotides.
Trends Pharmacol Sci. 1997;18:12-18.
35. Jachimczak P, Hessdorfer B, Fabel-Schulte K, et al. Transforming growth
factor-beta-mediated autocrine growth regulation of gliomas as detected with
phosphorothioate antisense oligodeoxynucleotides. Int J Cancer. 1996;65:332-337.
36. Miller PS. Antisense oligonucleotide methylphosphonates. Antisense RNA DNA.
1992:241-253.
37. Murray JM, Nishikura K. Application of antisense nucleic acids in oncology. In: Mol
JNM, van der Krol AR, eds. Antisense Nucleic Acids and Proteins. New York, NY: M.
Dekker; 1991:95-112.
38. Gryaznov SM, Lloyd DH, Chen JK, et al. Oligonucleotide N3'-->P5'
phosphoramidates. Proc Natl Acad Sci U S A. 1995;92: 5798-5802.
39. Stein CA. Antitumor effects of antisense phosphorothioate c-myc
oligodeoxynucleotides: a question of mechanism. J Natl Cancer Inst.
1996;88:391-393.
40. Gewirtz AM, Stein CA, Glazer PM. Facilitating oligonucleotide delivery: helping
antisense deliver on its promise. Proc Natl Acad Sci U S A. 1996;93:3161-3163.
41. Williams SA, Chang L, Buzby JS, et al. Cationic lipids reduce time and dose of c-myc
antisense oligodeoxynucleotides required to specifically inhibit Burkitt’s lymphoma
cell growth. Leukemia. 1996;10:1980-1989.
42. Citro G, Perrotti D, Cucco C, et al. Inhibition of leukemia cell proliferation by
receptor-mediated uptake of c-myb antisense oligodeoxynucleotides. Proc Natl
Acad Sci U S A. 1992;89:7031-7035.
43. Akhtar S, Basu S, Wickstrom E, et al. Interactions of antisense DNA oligonucleotide
analogs with phospholipid membranes (liposomes). Nucleic Acids Res.
1991;19:5551-5559.
44. Cazenave C, Helene C. Antisense oligonucleotides. In: Mol JNM, van der Krol AR,
eds. Antisense Nucleic Acids and Proteins. New York, NY: M. Dekker; 1991;47-93.
45. Carter G, Lemoine NR. Antisense technology for cancer therapy: does it make sense? Br
J Cancer. 1993;67:869-876.
46. Gura T. Antisense has growing pains. Science. 1995;270:575-577.
47. Aggarwal BB, Schwarz L, Hogan ME, et al. Triple helix-forming
oligodeoxyribonucleotides targeted to the human tumor necrosis factor (TNF) gene inhibit
TNF production and block the TNF-dependent growth of human glioblastoma tumor cells. Cancer
Res. 1996;56: 5156-5164.
48. Eng LF. Current antisense nucleic acid strategies for manipulating neuronal and
glial cells. Antisense Nucleic Acid Technology. New York, NY: Raven Press Ltd;
1993:293-310.
49. Okada T, Yamaguchi K, Yamashita Y. Triplex-forming oligonucleotide binding
represses transcription of the human c-erbB gene in glioma. Growth Factors.
1994;11:259-270.
50. Behl C, Winkler J, Bogdan U, et al. Autocrine growth regulation in neuroectodermal
tumors as detected with oligodeoxynucleotide antisense molecules. Neurosurgery.
1993;33:679-684.
51. Resnicoff M, Sell C, Rubini M, et al. Rat glioblastoma cells expressing an
antisense RNA to the insulin-like growth factor-1 (IGF-1) receptor are nontumorigenic and
induce regression of wild-type tumors. Cancer Res. 1994;54:2218-2222.
52. Nitta T, Sato K. Specific inhibition of c-sis protein synthesis and cell
proliferation with antisense oligodeoxynucleotides in human glioma cells. Neurosurgery.
1994;34:309-314.
53. Yazaki T, Ahmad S, Chahlavi A, et al. Treatment of glioblastoma U-87 by systemic
administration of an antisense protein kinase C-alpha phosphorothioate
oligodeoxynucleotide. Mol Pharmacol. 1996;50:236-242.
54. Yung WK. New approaches in brain tumor therapy using gene transfer and antisense
oligonucleoides. Curr Opin Oncol. 1994;6: 235-239.
55. Baltuch GH, Dooley NP, Rostworowski KM, et al. Protein kinase C isoform alpha
overexpression in C6 glioma cells and its role in cell proliferation. J Neurooncol.
1995;24:241-250.
56. Mercer WE, Ullrich SJ, Shields MT, et al. Cell cycle effects of microinjected
antisense oligodeoxynucleotides to p34cdc2 kinase. Ann N Y Acad Sci.
1992;660:209-218.
57. Merzak A, Koocheckpour S, Pilkington GJ. CD44 mediates human glioma cell adhesion
and invasion in vitro. Cancer Res. 1994;54:3988-3992.
58. Morrison RS. Suppression of basic fibroblast growth factor expression by antisense
oligodeoxynucleotides inhibits the growth of transformed human astrocytes. J Biol Chem.
1991;266:728-734.
59. Murphy PR, Sato Y, Knee RS. Phosphorothioate antisense oligonucleotides against
basic fibroblast growth factor inhibit anchorage-dependent and anchorage-independent
growth of a malignant glioblastoma cell line. Mol Endocrinol. 1992;6:877-884.
60. Selinfreund RH, Barger SW, Welsh MJ, et al. Antisense inhibition of glial S100 beta
production results in alterations in cell morphology, cytoskeletal organization and cell
proliferation. J Cell Biol. 1990; 111:2021-2028.
61. Van Eldik LJ, Barger SW, Welsh MJ. Antisense approaches to the function of glial
cell proteins. Ann N Y Acad Sci. 1992;660:219-230.
62. Burgess TL, Fisher EF, Ross SL, et al. The antiproliferative activity of c-myb
and c-myc antisense oligonucleotides in smooth muscle cells is caused by a
nonantisense mechanism. Proc Natl Acad Sci U S A. 1995;92:4051-4055.
63. Chavany C, Connell Y, Neckers L. Contribution of sequence and phosphorothioate
content to inhibition of cell growth and adhesion caused by c-myc antisense
oligomers. Mol Pharmacol. 1995;48:738-746.
64. Mahon FX, Ripoche J, Pigeonnier V, et al. Inhibition of chronic myelogenous
leukemia cells harboring a BCR-ABL B3A2 junction by antisense oligonucleotides targeted at
the B2A2 junction. Exp Hematol. 1995;23:1606-1611.
65. Weidner DA, Busch H. Antisense phosphorothioate oligonucleotides direct both
site-specific and nonspecific RNAse H cleavage of in vitro synthesized p120 mRNA. Oncol
Res. 1994;6:237-242.
66. Janicek MF, Angioli R, Unal AD, et al. p53 interference and growth inhibition in
p53-mutant and overexpressing endometrial cancer cell lines. Gynecol Oncol.
1997;66:94-102.
67. Saijo Y, Uchiyama B, Abe T, et al. Contiguous four-guanosine sequence in c-myc
antisense phosphorothioate oligonucleotides inhibits cell growth on human lung cancer
cells: possible involvement of cell adhesion inhibition. Jpn J Cancer Res.
1997;88:26-33.
68. Rockwell P, O’Conner WJ, King K, et al. Cell-surface perturbations of the
epidermal growth factor and vascular endothelial growth factor receptors by
phosphorothioate oligodeoxynucleotides. Proc Natl Acad Sci U S A.
1997;94:6523-6528.
69. Hartmann G, Krug A, Eigler A, et al. Specific suppression of human tumor necrosis
factor-alpha synthesis by antisense oligodeoxynucleotides. Antisense Nucleic Acid Drug
Dev. 1996;6: 291-299.
70. Perez JR, Li Y, Stein CA, et al. Sequence-independent induction of Sp1
transcription factor activity by phosphorothioate oligodeoxynucleotides. Proc Natl Acad
Sci U S A. 1994;91:5957-5961.
71. Ho PT, Ishiguro K, Wickstrom E, et al. Non-sequence-specific inhibition of
transferrin receptor expression in HL-60 leukemia cells by phosphorothioate
oligodeoxynucleotides. Antisense Res Dev. 1991;1:329-342.
72. Woolf TM, Jennings CG, Rebagliati M, et al. The stability, toxicity and
effectiveness of unmodified and phosphorothioate antisense oligodeoxynucleotides in
Xenopus oocytes and embryos. Nucleic Acid Res. 1990;18:1763-1769.
73. Levy RM, Ward S, Schalgeter K, et al. Alternative delivery systems for antiviral
nucleosides and antisense oligonucleotides to the brain. J Neuro Virology.
1997;3:S74-S75.
74. Wojcik WJ, Swoveland P, Zhang X, et al. Chronic intrathecal infusion of
phosphorothioate or phosphodiester antisense oligonucleotides against cytokine responsive
gene-2/IP-10 in experimental allergic encephalomyelitis of Lewis rat. J Pharmacol Exp
Ther. 1996;278:404-410.
75. Whitesell L, Geselowitz D, Chavany C, et al. Stability, clearance, and disposition
of intraventricularly administered oligodeoxynucleotides: implications for therapeutic
application within the central nervous system. Proc Natl Acad Sci U S A.
1993;90:4665-4669.
76. Yaida Y, Nowak TS Jr. Distribution of phosphodiester and phosphorothioate
oligonucleotides in rat brain after intraventricular and intrahippocampal administration
determined by in situ hybridization. Regul Pept. 1995;59:193-199.
77. Szklarczyk A, Kaczmarek L. Antisense oligodeoxyribonucleotides: stability and
distribution after intracerebral injection into rat brain. J Neurosci Methods.
1995;60:181-187.
78. Ogawa S, Brown HE, Okano HJ, et al. Cellular uptake of intracerebrally administered
oligodeoxynucleotides in mouse brain. Regul Pept. 1995;59:143-149.
79. Yee F, Ericson H, Reis DJ, et al. Cellular uptake of intracerebroventricularly
administered biotin- or digoxigenin-labeled antisense oligodeoxynucleotides in the rat. Cell
Mol Neurobiol. 1994;14:475-486.
80. Sun FY, Faden AI. Pretreatment with antisense oligodeoxynucleotides directed
against the NMDA-R1 receptor enhances survival and behavioral recovery following traumatic
brain injury in rats. Brain Res. 1995;693:163-168.
81. Bilsky EJ, Bernstein RN, Hruby VJ, et al. Characterization of antinociception to
opioid receptor selective agonists after antisense oligodeoxynucleotide-mediated
"knock-down" of opioid receptor in vivo. J Pharmacol Exp Ther.
1996;277:491-501.
82. Edsall SA, Knapp RJ, Vanderah TW, et al. Antisense oligodeoxynucleotide treatment
to the brain cannabinoid receptor inhibits antinociception. Neuroreport.
1996;7:593-596.
83. Skutella T, Schwarting RKW, Huston JP. Infusions of tyrosine hydroxylase antisense
oligodeoxynucleotide into substantia nigra of the rat: effects on tyrosine hydroxylase
mRNA and protein content, striatal dopamine release and behaviour. Eur J Neurosci.
1997;9:210-220.
84. Quercia S, Chang SL. Antisense oligodeoxynucleotide attenuates in vivo
expression of c-fos in the paraventricular hypothalamic nucleus of the rat brain. Neurosci
Lett. 1996;209:89-92.
85. Zapata A, Capdevila JL, Tarrason G, et al. Effects of NMDA-R1 antisense
oligodeoxynucleotide administration: behavioral and radioligand binding studies. Brain
Res. 1997;745:114-120.
86. Aguan K, Mehesh VB, Ping L, et al. Evidence for a physiological role for nitric
oxide in the regulation of the LH surge: effect of central administration of antisense
oligonucleotides to nitric oxide synthase. Neuroendocrinology. 1996;64:449-455.
87. Ogawa S, Olazabal UE, Parhar IS, et al. Effects of intrahypothalamic administration
of antisense DNA for progesterone receptor mRNA on reproductive behavior and progesterone
receptor immunoreactivity in female rat. J Neurosci. 1994;14:1766-1774.
88. Sakai RR, Ma LY, He PF, et al. Intracerebroventricular administration of
angiotensin type 1 (AT1) receptor antisense oligonucleotides attenuate thirst in the rat. Regul
Pept. 1995;59:183-192.
89. Sakai RR, He PF, Yang XD, et al. Intracerebroventricular administration of AT1
receptor antisense oligonucleotides inhibits the behavioral actions of angiotensin II.
J Neurochem. 1994;62:2053-2056.
90. McCarthy MM, Masters DB, Rimvall K, et al. Intracerebral administration of
antisense oligodeoxynucleotides to GAD65 and GAD67 mRNAs modulate reproductive behavior in
the female rat. Brain Res. 1994;636:209-220.
91. Guzowski JF, McGaugh JL. Antisense oligodeoxynucleotide-mediated disruption of
hippocampal cAMP response element binding protein levels impairs consolidation of memory
for water maze training. Proc Natl Acad Sci U S A. 1997;94:2693-2698.
92. Zhou LW, Zhang SP, Weiss B. Intrastriatal administration of an oligodeoxynucleotide
antisense to the D2 dopamine receptor mRNA inhibits D2 dopamine receptor-mediated behavior
and D2 dopamine receptors in normal mice and in mice lesioned with 6-hydroxydopamine. Neurochem
Int. 1996;29:583-595.
93. Reul JM, Probst JC, Skutella T, et al. Increased stress-induced adrenocorticotropin
response after long-term intracerebroventricular treatment of rats with antisense
mineralocorticoid receptor oligodeoxynucleotides. Neuroendocrinology.
1997;65:189-199.
94. Akabayashi A, Wahlestedt C, Alexander JT, et al. Specific inhibition of endogenous
neuropeptide Y synthesis in arcuate nucleus by antisense oligonucleotides suppresses
feeding behavior and insulin secretion. Brain Res Mol Brain Res. 1994;21:55-61.
95. Wielbo D, Sernia C, Gyurko R, et al. Antisense inhibition of hypertension in the
spontaneously hypertensive rat. Hypertension. 1995;25:314-319.
96. Landgraf R, Gerstberger R, Montkowksi A, et al. V1 vasopressin receptor antisense
oligodeoxynucleotide into septum reduces vasopressin binding, social discrimination
abilities, and anxiety-related behavior in rats. J Neurosci. 1995;15:4250-4258.
97. Hulsey MG, Pless CM, White BD, et al. ICV administration of anti-NPY antisense
oligonucleotide: effects on feeding behavior, body weight, peptide content and peptide
release. Regul Pept. 1995;59:207-214.
98. Sanchez-Blazquez P, Garcia-Espana A, Garzon J. In vivo injection of
antisense oligodeoxynucleotides to G alpha subunits and supraspinal analgesia evoked by mu
and delta opioid agonists. J Pharmacol Exp Ther. 1995;275:1590-1596.
99. Pezeshki G, Schobitz B, Pohl T, et al. Intracerebroventricular administration of
missense oligodeoxynucleotide induces interleukin-6 mRNA expression in brain and spleen of
rats. Neurosci Lett. 1996;217:97-100.
100. Yamada K, Moriguchi A, Morishita R, et al. Efficient oligonucleotide delivery
using the HVJ-liposome method in the central nervous system. Am J Physiol.
1996;271:R1212-1220.
101. Wickstrom E, Bacon TA, Wickstrom EL. Down-regulation of c-MYC antigen expression
in lymphocytes of Emu-c-myc transgenic mice treated with anti-c-myc DNA
methylphosphonates. Cancer Res. 1992;52:6741-6745.
102. Whitesell L, Rosolen A, Neckers LM. In vivo modulation of N-myc
expression by continuous perfusion with an antisense oligonucleotide. Antisense Res Dev.
1991;1:343-350.
103. Kitajima I, Shinohara T, Bilakovics J, et al. Ablation of transplanted HTLV-I
Tax-transformed tumors in mice by antisense inhibition of NF-kappa B. Science.
1992;258:1792-1795.
104. Bayever E, Iversen P, Smith L, et al. Guest editorial: systemic human antisense
therapy begins. Antisense Res Dev. 1992;2:109-110.
105. Bishop MR, Iversen PL, Bayever E, et al. Phase I trial of an
antisense oligonucleotide OL(1)p53 in hematologic malignancies. J Clin Oncol.
1996;14:1320-1326.
From the Division of Neurological Surgery, Department of Surgery, and the Experimental
Neuro-Oncology Program, Northwestern University Medical School, Chicago, Ill.
Address reprint requests to Herbert H. Engelhard, MD, PhD,
Neurological Surgery, Northwestern University Medical School, Ste 500, 233 E Erie St,
Chicago, IL 60611.
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