Therapeutically Promising PNA Complementary to a Regulatory Sequence for c-myc:Pharmacokinetics in an Animal Model of Human Burkitt's Lymphoma (original) (raw)
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Cancer Gene Therapy, 2007
In Burkitt's lymphoma (BL) cells due to a t(8;14) chromosomal translocation c-myc is often placed in proximity to the Em enhancer of the Ig locus and upregulated. We demonstrated that in BL cells a peptide nucleic acid (PNA), complementary to intronic Em sequences (PNAEmwt), specifically blocks the expression of the c-myc oncogene under the Em enhancer control and inhibits BL cell growth in culture. Here, we investigated whether PNAEmwt was also able to block tumor growth in SCID mice inoculated with human BL cell lines. After subcutaneous inoculum in mice BL cells reproducibly form tumors. Both pre-treatment of BL cells with PNAEmwt before inoculum and chronic intravenous administration of PNAEmwt to mice already inoculated with BL cells selectively caused increased latency of tumor appearance and decreased final tumor size. Tumors from PNAEmwt-treated animals showed substantial areas of cell necrosis and of c-myc downregulation. Inhibition of tumor growth was specific and was not observed with PNAEmmut carrying sequence mutations and in BL cell lines where the translocated c-myc is not under the control of the Em enhancer. These data confirm the potential therapeutic value of PNA targeted to regulatory non-coding regions.
Cancer research, 2003
In Burkitt's Lymphoma there is an up-regulation of the c-myc oncogene caused by its translocation from chromosome 8 to chromosome 14, often close to the E mu enhancer of the immunoglobulin heavy chain locus (IgH). In Burkitt's Lymphoma cells, a peptide nucleic acid complementary for a specific unique E mu intronic sequence selectively blocked the expression of the c-myc oncogene under E mu control but not of other c-myc alleles. This Peptide Nucleic Acid also inhibited IgM expression in B cells. The finding that PNAs specific for a regulatory noncoding sequence can block gene expression has important conceptual and practical implications.
PubMed, 1998
c-Myc is a nuclear protein with important roles in cell transformation, cell proliferation, and gene transcription. It has been previously shown that a 14-amino acid (aa) modified peptide (H1-S6A,F8A) derived from the helix 1 (H1) carboxylic region of c-Myc can interfere in vitro with specific c-Myc DNA binding. Here, we have linked the above Myc-derived 14-aa peptide to a 16-aa sequence from the third helix of Antennapedia (Int). It has been repeatedly reported that this 16-aa Antennapedia peptide is able to cross mammalian cell membranes and to work as a vector for short peptides. Using fluorescent (dansylated or rhodaminated) peptides, we have shown that the fusion peptide with the Antennapedia fragment (Int-H1-S6A,F8A) but not the c-Myc derived fragment alone (H1-S6A,F8A) was capable of internalization inside MCF-7 human breast cancer cells. Int-H1-S6A,F8A and H1-S6A,F8A were the only two peptides capable of inhibiting coimmunoprecipitation of the c-Myc/Max heterodimer in vitro. We have treated (continuously for 10-11 days) MCF-7 cells with four different peptides: Int, H1-S6A,F8A, Int-H1-S6A,F8A, and Int-H1wt [a peptide differing from Int-H1-S6A,F8A by 2 aa (S6 and F8) in the H1 region]. In intact MCF-7 cells, Int-H1-S6A,F8A was the only active peptide capable of inducing the following biological effects: (a) inhibition of cloning efficiency on plates; (b) inhibition of cell growth and induction of apoptosis in subconfluent/confluent cells; and (c) inhibition of transcription of two c-Myc-regulated genes (ODC and p53). Int-H1-S6A,F8A was active in the 1-10 microM range. Int-H1-S6A,F8A may represent a lead molecule for peptidomimetic compounds that have a similar three-dimensional structure but are more resistant to peptidases and, therefore, suitable for in vivo treatment of experimentally induced tumors.
Biochemistry, 2000
Triple helix-forming oligonucleotides (TFOs) bind with high affinity and specificity to homopurine-homopyrimidine sequences in DNA and have been shown to inhibit transcription of target genes in various experimental systems. In the present study, we evaluated the ability of 3′-amino-modified phosphodiester TFOs directed to four sites in the c-myc gene to inhibit gene expression and proliferation of human leukemia (CEM, KG-1, and HL-60) and lymphoma (Raji and ST486) cells. GT-rich TFOs were designed to target sequences located either upstream (myc1 and -2) or downstream (myc3 and -4) of the P2 promoter, which is the major c-myc promoter. Myc2, which was directed to a site immediately upstream of this promoter, inhibited c-myc expression and proliferation of CEM cells. The effects of this TFO were sequence-and target-specific, since control oligonucleotides and TFOs directed to other sites were less or not active. Myc2 was also effective in KG-1, HL-60, and Raji cells. In contrast, ST486 cells were more sensitive to myc3, which targets a sequence in intron 1 upstream of the P3 promoter, than myc2. As result of a chromosomal translocation, P3 is the active promoter in ST486 cells. This study demonstrates the activity and specificity of TFOs designed to act as repressors of c-myc gene expression in human leukemia and lymphoma cells. Our results suggest that this is a valid approach to selectively inhibit gene expression and cancer cell growth, and encourage further investigation of its potential applications in cancer therapy.
Cancer Gene Therapy, 2009
In human Burkitt's Lymphoma (BL) BRG cells, a t(8;14) translocation, placing c-myc near the Em enhancer of the H chain locus, causes tumor expansion. Earlier, we showed that a peptide nucleic acid complementary to the Em sequence (PNAEm), specifically inhibited the expression of translocated c-myc and impaired the growth of BRG cells-induced subcutaneous tumors in mice suffering from severe combined immunodeficiency (SCID). In this study, the therapeutic potential of PNAEm was evaluated in a systemic mouse model. BRG-BL cells transfected with the luciferase gene were inoculated intravenously into SCID mice resulting in a preferential expansion, similar to the one of human adult patients, in the abdominal cavity, central nervous system and bone marrow. The mice were chronically injected intraperitoneally either with PNAEm or with control PNA. The treatment was stopped when the control animals developed severe neurological symptoms. As detected both by inspection at necropsy and imaging, overall tumor growth in PNAEm-treated mice decreased by 480%. Histological and immunohistochemical studies showed, only in PNAEm-treated mice, a substantially reduced BL cell growth at the major sites of invasion and vast areas of necrosis in the lymphomatous tissues, with concomitant c-myc expression downregulation. Altogether, the data support the therapeutic potential of PNAEm in human adult BL.
The FASEB Journal, 2000
In 1998 we reported that an L-peptide derived from H1 of c-Myc (Int-H1-S6A,F8A), linked to an internalization sequence from the third α-helix of Antennapedia, was endowed with an antiproliferative and proapoptotic activity toward a human mammary cancer cell line: The activity apparently depends upon the presence of the Myc motif. In the present work we have added new dimensions to our original findings. It is known that short retro-inverso (RI-) peptides can assume a 3D conformation very close to their corresponding L-forms and can be recognized by the same monoclonal antibody. We synthesized a RI-peptide form of our original L-peptide: It was much more resistant to serum peptidases than the original molecule (a half life of days rather than hours); in addition, the RI-form of the original Antennapedia internalization sequence was perfectly capable of carrying a D-peptide into human cells. We have studied three different potentially active peptides. L-peptides: Int-H1wt, Int-H1-S6A,F8A. Dpeptides: RI-Int-H1-S6A,F8A. We have also studied three presumed control peptides: Int and RI-Int (no H1 motif), H1-S6A,F8A (no internalization sequence). Both 'active' and 'control' peptides have essentially confirmed our expectations, however, in cells treated with the higher concentration (10 µM) of the control peptide RI-Int, non-Myc related side effects could be detected. In order to investigate whether the antiproliferative activities displayed by some of our molecules were indeed related to an interference with the role of c-Myc (and molecules of the family), we chose an iso-amphipathic modified peptide of the H1 motif, with a proximity coefficient >50% and where the major change was at position 7 (F→A). From a family of 73 H1 motifs belonging to (H1-Loop-H2) human sequences, the smallest evolutionary distance from our reference peptide was observed for the H1 of N-Myc, L-Myc, c-Myc, H1-S6A,F8A of c-Myc, and Max, in that order. Our reference peptide was therefore appropriate as a check of whether we were indeed observing activities related to Myc functions. Both Int-H1isoamph and the corresponding RI-Int-H1isoamph peptide were synthesized and studied. In terms of biological targets, we added to the human mammary cancer line of our previous work (MCF-7 cells) a colon cancer line (HCT-116 cells) and also a system of normal cells: human peripheral blood lymphocytes (PBLs) stimulated with phytohemoagglutinin (PHA). Peptides carrying an iso-amphipathic-modified H1 sequence were always very clearly (3-10 times) less active than the corresponding peptides carrying a conserved "H1 of Myc" motif. This finding was noted in five independent situations (all the cellular models considered at the present time): MCF-7 cells treated with L-peptides; MCF-7 cells treated with RI-peptides; HCT-116 cells treated with L-peptides; PBLs treated with L-peptides; PBLs treated with RI-peptides. Modulation of transcription levels of ornithine decarboxylase (ODC), p53, and glyceraldehyde-3-phosphate dehydrogenase (GAPDH), in PBLs treated with our different molecules, was well compatible with an interference by our active peptides at the level of Myc transcriptional activity. We had already reported a similar observation in MCF-7 cells. On a molar basis, RI-peptides were about 5-10 times more potent and 30-35 times more stable in complete culture medium, than their corresponding L-forms. RI-Int can probably internalize longer peptido-mimetic molecules (for instance molecules mimetic of (H1-Loop-H2), or even more. These possibilities open the way to rodent studies and to more potent/selective Myc inhibitors-two steps closer to a potential drug.
Inhibition of tumorigenicity by the 5′-untranslated RNA of the human c-myc P0 transcript
Experimental Cell Research, 2003
Activity of the independently regulated human c-myc P0 promoter has been associated with the undifferentiated status of leukemia cells as well as the hormone-independent proliferation of breast cancer cells. The P0 transcript is distinguished from the predominant P1 and P2 c-myc mRNAs by an approximately 639-nucleotide extension of the 5'-untranslated region. We hypothesized that this complex 5'-untranslated RNA sequence unique to the P0 transcript may contribute significantly to the composite regulation of the c-myc locus and that enforced intracellular synthesis of the isolated P0 5'-UTR, out of its native sequence context, might amplify or dominantly interfere with its normal regulatory function. Human tumor (HeLa) cells in which the isolated P0 5'-UTR was ectopically expressed displayed a dramatic decrease in anchorage-independent proliferation. Furthermore, P0 5'-UTR-expressing HeLa cells failed to form tumors when inoculated into SCID mice. This loss of tumorigenicity was associated with increases in levels of the c-Myc1 (p67) and c-Myc2 (p64) proteins and a 3- to 5-fold elevation of spontaneous apoptotic index. These results demonstrate that an isolated 5'-untranslated RNA sequence can be attributed potent in trans gene-regulatory and phenotype-altering capabilities and that extrinsic alterations in c-myc regulation can be utilized to reestablish the natural proapoptotic (tumor suppressor) activities associated with this protooncogene.
Deregulation of the proto-oncogene c-myc through t(8;22) translocation in Burkitt's lymphoma
Oncogene, 1999
In Burkitt's lymphoma (BL) cells the proto-oncogene cmyc is juxtaposed to one of the immunoglobulin (Ig) loci on chromosomes 2, 14, or 22. The c-myc gene becomes transcriptionally activated as a consequence of the chromosomal translocation and shows preferential usage of promoter P1 over P2, a phenomenon referred to as promoter shift. In order to de®ne the responsible regulatory elements within the Ig l locus, we studied the eect of the human Ig l enhancer (HuEl) on c-myc expression after stable transfection into BL cells. A 12 kb genomic fragment encompassing HuEl, but not HuEl alone, strongly activated c-myc expression and induced the promoter shift. To identify additional elements involved in c-myc deregulation, we mapped DNaseI hypersensitive sites within the 12 kb l fragment on the construct. Besides one hypersensitive site corresponding to HuEl, three additional sites were detected. Two of these elements displayed enhancer activity after transient transfection. The third element did not activate c-myc transcription, but was required for full c-myc activation and promoter shift. Deletion analyses of the c-myc promoter identi®ed the immediate promoter region as sucient for activation by the Ig l locus, but also revealed that induction of the promoter shift requires additional upstream elements.