Anti-Cancer Peptide PNC-27 Kills Cancer Cells by Unique Interactions with Plasma Membrane-Bound hdm-2 and with Mitochondrial Membranes Causing Mitochondrial Disruption.

OBJECTIVE: We have previously shown that the anti-cancer peptide PNC-27 kills cancer cells by co-localizing with membrane-expressed HDM-2, resulting in transmembrane pore formation causing extrusion of intracellular contents. We have also observed cancer cell mitochondrial disruption in PNC-27-treated cancer cells. Our objectives are to determine: 1. if PNC-27 binds to the p53 binding site of HDM-2 (residues 1-109) in the cancer cell membrane and 2. if this peptide causes selective disruption of cancer cell mitochondria. METHODS: For aim 1, we incubated MIA-PaCa-2 human pancreatic carcinoma cells with PNC-27 in the presence of a monoclonal antibody against the amino terminal p53 binding site of HDM-2 to determine if it, but not negative control immune serum, blocks PNC-27-induced tumor cell necrosis. For the second aim, we incubated these cells with PNC-27 in the presence of two specific dyes that highlight normal organelle function: mitotracker for mitochondria and lysotracker for lysosomes. We also performed immuno-electron microscopy (IEM) with gold-labeled anti-PNC-27 antibody on the mitochondria of these cells treated with PNC-27. RESULTS: Monoclonal antibody to the p53 binding site of HDM-2 blocks PNC-27-induced cancer cell necrosis, whereas negative control immune serum does not. The mitochondria of PNC-27-treated cancer cells fail to retain mitotracker dye while their lysosomes retain lysotracker dye. IEM of the mitochondria cancer cells reveals gold particles present on the mitochondrial membranes. CONCLUSIONS: PNC-27 binds to the p53 binding site of HDM-2 (residues 1-109) inducing transmembrane pore formation and cancer cell necrosis. Furthermore, this peptide enters cancer cells and binds to the membranes of mitochondria, resulting in their disruption.

The anti-cancer peptide, PNC-27, induces tumor cell necrosis of a poorly differentiated non-solid tissue human leukemia cell line that depends on expression of HDM-2 in the plasma membrane of these cells.

GOALS: We have developed the anti-cancer peptide, PNC-27, which is a membrane-active peptide that binds to the HDM-2 protein expressed in the cancer cell membranes of solid tissue tumor cells and induces transmembrane pore formation in cancer, but not in normal cells, resulting in tumor cell necrosis that is independent of p53 activity in these cells. We now extend our study to non-solid tissue tumor cells, in this case, a primitive, possible stem cell human leukemia cell line (K562) that is also p53-homozygously deleted. Our purpose was twofold: to investigate if these cells likewise express HDM-2 in their plasma membranes and to determine if our anti-cancer peptide induces tumor cell necrosis in these non-solid tissue tumor cells in a manner that depends on the interaction between the peptide and membrane-bound HDM-2. PROCEDURES: The anti-cancer activity and mechanism of PNC-27, which carries a p53 aa12-26-leader sequence connected on its carboxyl terminal end to a trans-membrane-penetrating sequence or membrane residency peptide (MRP), was studied against p53-null K562 leukemia cells. Murine leukocytes were used as a non-cancer cell control. Necrosis was determined by measuring the lactate dehydrogenase (LDH) release and apoptosis was determined by the detection of Caspases 3 and 7. Membrane colocalization of PNC-27 with HDM-2 was analyzed microscopically using fluorescently labeled antibodies against HDM-2 and PNC-27 peptides. RESULTS: We found that K562 cells strongly express HDM-2 protein in their membranes and that PNC-27 co-localizes with this protein in the membranes of these cells. PNC-27, but not the negative control peptide PNC-29, is selectively cytotoxic to K562 cells, inducing nearly 100 percent cell killing with LDH release. In contrast, this peptide had no effect on the lymphocyte control cells. CONCLUSIONS: The results suggest that HDM-2 is expressed in the membranes of non-solid tissue tumor cells in addition to the membranes of solid tissue tumor cells. Since K-562 cells appear to be in the stem cell family, the results suggest that early developing tumor cells also express HDM-2 protein in their membranes. Since PNC-27 induces necrosis of K-562 leukemia cells and co-localizes with HDM-2 in the tumor cell membrane as an early event, we conclude that the association of PNC-27 with HDM-2 in the cancer cell membrane results in trans-membrane pore formation which results in cancer cell death, as previously discovered in a number of different solid tissue tumor cells. Since K562 cells lack p53 expression, these effects of PNC-27 on this leukemia cell line occur by a p53-independent pathway.

Anti-cancer peptides from ras-p21 and p53 proteins.

We have employed computer-based molecular modeling approaches to design peptides from the ras-p21 and p53 proteins that either induce tumor cell reversion to the untransformed phenotype or induce tumor cell necrosis without affecting normal cells. For rasp21, we have computed and superimposed the average low energy structures for the wild-type protein and oncogenic forms of this protein and found that specific domains change conformation in the oncogenic proteins. We have synthesized peptides corresponding to these and found that ras peptides, 35-47 (PNC-7) and 96-110 (PNC-2), block oncogenic ras-p21-induced oocyte maturation but have no effect on insulin-induced oocyte maturation that requires activation of endogenous wild-type ras-p21. These results show signal transduction pathway differences between oncogenic and activated wild-type ras-p21. Both peptides, attached to a membrane-penetrating peptide (membrane residency peptide or MRP), either induce phenotypic reversion to the untransformed phenotype or tumor cell necrosis of several ras-transformed cell lines, but have no effect on the growth of normal cells. Using other computational methods, we have designed two peptides, PNC-27 and 28, containing HDM-2-protein-binding domain sequences from p53 linked on their C-termini to the MRP that induce pore formation in the membranes of a wide range of cancer cells but not any normal cells tested. This is due to the expression of HDM-2 in the cancer cell membrane that does not occur in normal cells. These peptides eradicate a highly malignant tumor in nude mice with no apparent side effects. Both ras and p53 peptides show promise as anti-tumor agents in humans.

The anti-cancer peptide, PNC-27, induces tumor cell lysis as the intact peptide.

PURPOSE: PNC-27, a peptide that contains an HDM-2-binding domain from p53 attached to a membrane-penetrating peptide on its carboxyl terminal end, is cytotoxic to cancer, but not normal, cells. It forms transmembrane pores in the cancer cell membrane. Our purpose is to determine if the whole peptide or critical fragments induce pore formation in cancer cells. METHODS: We have prepared PNC-27 with a green fluorescent label on its amino terminus and a red fluorescent label on its carboxyl terminus and treated MCF-7 breast cancer cells and untransformed MCF-10-2A breast epithelial cells with this double-labeled peptide to determine if combined yellow fluorescence occurs in the membrane of the cancer cells during cancer cell killing. RESULTS: At 30 min, there is significant combined punctate yellow fluorescence, indicative of intact peptide, in the cell membrane of cancer cells that increases during cancer cell lysis. MCF-10-2A cells show initial (30 min) uniform combined yellow membrane fluorescence that subsequently disappears. Unlike the cancer cells, these untransformed cells remain viable. CONCLUSIONS: PNC-27 induces cancer cell membrane lysis by acting as the whole peptide, not fragments. The punctate yellow fluorescence is due to interaction of PNC-27 with intramembrane targets of MCF-7 cells that do not exist in the membrane of the untransformed cell line. This interaction increases the lifetime of PNC-27. Absence of these targets in the membranes of the untransformed MCF-10-2A cells results in initial uniform fluorescence of the double-labeled peptide in their membranes after which the peptide is degraded.

Anticancer peptide PNC-27 adopts an HDM-2-binding conformation and kills cancer cells by binding to HDM-2 in their membranes.

The anticancer peptide PNC-27, which contains an HDM-2-binding domain corresponding to residues 12-26 of p53 and a transmembrane-penetrating domain, has been found to kill cancer cells (but not normal cells) by inducing membranolysis. We find that our previously determined 3D structure of the p53 residues of PNC-27 is directly superimposable on the structure for the same residues bound to HDM-2, suggesting that the peptide may target HDM-2 in the membranes of cancer cells. We now find significant levels of HDM-2 in the membranes of a variety of cancer cells but not in the membranes of several untransformed cell lines. In colocalization experiments, we find that PNC-27 binds to cell membrane-bound HDM-2. We further transfected a plasmid expressing full-length HDM-2 with a membrane-localization signal into untransformed MCF-10-2A cells not susceptible to PNC-27 and found that these cells expressing full-length HDM-2 on their cell surface became susceptible to PNC-27. We conclude that PNC-27 targets HDM-2 in the membranes of cancer cells, allowing it to induce membranolysis of these cells selectively.

The penetratin sequence in the anticancer PNC-28 peptide causes tumor cell necrosis rather than apoptosis of human pancreatic cancer cells.

BACKGROUND: PNC-27 and PNC-28 are p53-derived peptides from the human double minute (hdm-2) binding domain attached to penetratin. These peptides induce tumor cell necrosis of cancer cells, but not normal cells. The anticancer activity and mechanism of PNC-28 (p53 aa17-26-penetratin) was specifically studied against human pancreatic cancer. METHODS: MiaPaCa-2 cells were treated with PNC-28. Necrosis was determined by measuring lactate dehydrogenase (LDH) and apoptosis as assayed for measuring elevation of proapoptotic proteins. PNC-29, an unrelated peptide, and hdm-2-binding domain p53 aa12-26 without penetratin (PNC-26) were used as controls. Since there is evidence that penetratin is required for tumor cell necrosis, we tested "naked" p53 peptide without penetratin by transfecting a plasmid that encodes p53 aa17-26 segment of PNC-28 into MiaPaCa-2 and an untransformed rat pancreatic acinar cell line, BMRPA1. Time-lapse electron microscopy was employed to further elucidate anticancer mechanism. RESULTS: Treatment with PNC-28 does not result in the elevation of proapoptotic proteins found in p53-induced apoptosis, but elicits rapid release of LDH, indicative of tumor cell necrosis. Accordingly, we observed membrane pore formation and dose-dependent killing. In direct contrast, transfected MiaPaCa-2 cells underwent apoptosis, and not necrosis, as evidenced by expression of high levels of caspases-3 and 7 and annexin V with background levels of LDH. CONCLUSION: These results suggest that PNC-28 may be effective in treating human pancreatic cancer. The penetratin sequence appears to be responsible for the fundamental change in the mechanism of action, inducing rapid necrosis initiated by membrane pore formation. Cancer cell death by apoptosis was observed in the absence of penetratin.

Site-specific phosphorylation of raf in cells containing oncogenic ras-p21 is likely mediated by jun-N-terminal kinase.

In a study of interactions between the raf-MEK-MAPK (ERK) and JNK-jun pathways, we found previously that JNK can induce phosphorylation of raf but not vice versa. In this study, we investigate the nature of the JNK-induced phosphorylation of raf. In in vitro experiments in which immunobead-bound raf is phosphorylated by activated JNK, we find strong phosphorylation signals at raf-Ser259 and Ser338. The Ser259 phosphorylation is surprising since it is associated with inhibition of migration of raf to the cell membrane where it can interact with ras-p21. We also find that in oocytes induced to mature with oncogenic ras-p21, which induces high levels of phosphorylated JNK and MAPK, the same pattern of phosphorylation of raf occurs. In contrast, in oocytes induced to mature with insulin, which requires activation of wild-type ras-p21, phosphorylation of raf-Ser338 but not raf-Ser259 occurs. In oncogenic ras-transformed human pancreatic cancer MIA-PaCa-2 cells, phosphorylation of both raf serines occurs. Treatment of these cells with the ras peptide, PNC-2 attached to a penetrating sequence that blocks JNK and MAPK phosphorylation and induces tumor cell necrosis, results in a marked decrease in phosphorylation of raf-Ser259, but not that of raf-Ser338. These results suggest that oncogenic ras-p21 induces phosphorylation of both raf-Ser259 and Ser338 and that raf-Ser 259 phosphorylation may be effected by activated JNK.

Two peptides derived from ras-p21 induce either phenotypic reversion or tumor cell necrosis of ras-transformed human cancer cells.

PURPOSE: We investigated the effects of two peptides from the ras-p21 protein, corresponding to residues 35-47 (PNC-7) and 96-110 (PNC-2), on two ras-transformed human cancer cell lines, HT1080 fibrosarcoma and MIAPaCa-2 pancreatic cancer cell lines. In prior studies, we found that both peptides block oncogenic, but not insulin-activated wild-type, ras-p21-induced oocyte maturation. When linked to a transporter penetratin peptide, these peptides induce reversion of ras-transformed rat pancreatic cancer cells (TUC-3) to the untransformed phenotype. METHODS: These peptides and a control peptide, linked to a penetratin peptide, were incubated with each cell lines. Cell counts were obtained over several weeks. The cause of cell death was determined by measuring caspase as an indicator of apoptosis and lactate dehydrogenase (LDH) as marker of necrosis. Since both peptides block the phosphorylation of jun-N-terminal kinase (JNK) in oocytes, we blotted cell lysates of the two cancer cell lines for the levels of phosphorylated JNK to determine if the peptides reduced these levels. RESULTS: We find that both peptides, but not control peptides linked to the penetratin sequence, induce phenotypic reversion of the HT-1080 cell line but cause tumor cell necrosis of the MIA-PaCa-2 cell line. On the other hand, neither peptide has any effect on the viability of an untransformed pancreatic acinar cell line, BMRPA1. We find that, while total JNK levels remain constant during peptide treatment, phosphorylated JNK levels decrease dramatically, consistent with the mechanisms of action of these peptides. CONCLUSION: We conclude that these peptides block tumor but not normal cell growth likely by blocking oncogenic ras-p21-induced phosphorylation of JNK, an essential step on the oncogenic ras-p21-protein pathway. These peptides are therefore promising as possible anti-tumor agents.

The dual-specificity kinases, TOPK and DYRK1A, are critical for oocyte maturation induced by wild-type--but not by oncogenic--ras-p21 protein.

We have previously found that oncogenic ras-p21 and insulin, which activates wild-type ras-21 protein, both induce Xenopus laevis oocyte maturation that is dependent on activation of raf. However, oncogenic ras-p21 utilizes raf-dependent activation of the two classic raf targets, MEK and MAP kinase (MAPK or ERK) while insulin-activated wild-type ras-p21 does not depend on activation of these two kinases. Utilizing a microarray containing the entire Xenopus genome, we discovered two dual specificity kinases, T-Cell Origin Protein Kinase (TOPK), known to bind to raf and the nuclear kinase, DYRK1A, that are expressed at much higher levels in insulin-matured oocytes. Using SiRNA's directed against expression of both of these proteins, we now show that each inhibits insulin-but not oncogenic ras-p21-induced oocyte maturation. Control siRNA's have no effect on either agent in induction of maturation. We find that each SiRNA "knocks down" expression of its target protein while not affecting expression of the other protein. These results suggest that both proteins are required for maturation induced by wild-type, but not oncogenic, ras-p21. They also suggest that oncogenic and wild-type ras-p21 utilize pathways that become divergent downstream of raf. On the basis of these findings, we propose a model for two signal transduction pathways by oncogenic and activated wild-type ras-p21 showing points of overlap and divergence.

Alpha2-macroglobulin is a potential facilitator of prion protein transformation.

Cellular prion protein changes conformation during transformation to an infectious scrapie isoform. One measure of transformation is the development of partial resistance to protease treatment. A fraction of human and bovine plasma was identified containing activity that facilitates transformation of cellular prion protein to a protease resistant isoform in the presence of RNA in the absence of seeded scrapie prion protein. Purification of proteins from this fraction led to the identification of alpha2-macroglobulin as an active component suggesting that it may facilitate conformational changes in prion protein in spontaneous forms of prion disease.

Two dual specificity kinases are preferentially induced by wild-type rather than by oncogenic RAS-P21 in Xenopus oocytes.

In prior studies, we have found that oncogenic ras-p21 protein induces oocyte maturation using pathways that differ from those activated by insulin-induced wild-type ras-p21. Both oncogenic and wild-type ras-p21 require interactions with raf, but unlike oncogenic ras-p21, insulin-activated wild-type ras-p21 does not depend completely on activation of MEK and MAP kinase (MAPK or ERK) on the raf kinase pathway. To determine what raf-dependent but MAPK-independent pathway is activated by wild-type ras-p21, we have analyzed gene expression in oocytes induced to mature either with oncogenic ras-p21 or with insulin using a newly available Xenopus gene array. We find a number of proteins that are preferentially expressed in one or the other system. Of these, two proteins, both dual function kinases, T-Cell Origin Protein Kinase (TOPK) and the nuclear kinase, DYRK1A, are preferentially expressed in the insulin system. Confirming this finding, blots of lysates of oocytes, induced to mature with oncogenic ras-p21 and insulin, with anti-TOPK and anti-DYRK1A show much higher protein expression in the lysates from the insulin-matured oocytes. Neither of these kinases activates or is activated by MAPK and is therefore an attractive candidate for being on a signal transduction pathway that is unique to insulin-activated wild-type ras-p21-induced oocyte maturation.

Functional interactions of Raf and MEK with Jun-N-terminal kinase (JNK) result in a positive feedback loop on the oncogenic Ras signaling pathway.

In previous studies we have found that oncogenic (Val 12)-ras-p21 induces Xenopus laevis oocyte maturation that is selectively blocked by two ras-p21 peptides, 35-47, also called PNC-7, that blocks its interaction with raf, and 96-110, also called PNC-2, that blocks its interaction with jun-N-terminal kinase (JNK). Each peptide blocks activation of both JNK and MAP kinase (MAPK or ERK) suggesting interaction between the raf-MEK-ERK and JNK-jun pathways. We further found that dominant negative raf blocks JNK induction of oocyte maturation, again suggesting cross-talk between pathways. In this study, we have undertaken to determine where these points of cross-talk occur. First, we have immunoprecipitated injected Val 12-Ha-ras-p21 from oocytes and found that a complex forms between ras-p21 raf, MEK, MAPK, and JNK. Co-injection of either peptide, but not a control peptide, causes diminished binding of ras-p21, raf, and JNK. Thus, one site of interaction is cooperative binding of Val 12-ras-p21 to raf and JNK. Second, we have injected JNK, c-raf, and MEK into oocytes alone and in the presence of raf and MEK inhibitors and found that JNK activation is independent of the raf-MEK-MAPK pathway but that activated JNK activates raf, allowing for activation of ERK. Furthermore, we have found that constitutively activated MEK activates JNK. We have corroborated these findings in studies with isolated protein components from a human astrocyte (U-251) cell line; that is, JNK phosphorylates raf but not the reverse; MEK phosphorylates JNK but not the reverse. We further have found that JNK does not phosphorylate MAPK and that MAPK does not phosphorylate JNK. The stress-inducing agent, anisomycin, causes activation of JNK, raf, MEK, and ERK in this cell line; activation of JNK is not inhibitable by the MEK inhibitor, U0126, while activation of raf, MEK, and ERK are blocked by this agent. These results suggest that activated JNK can, in turn, activate not only jun but also raf that, in turn, activates MEK that can then cross-activate JNK in a positive feedback loop.

An effector peptide from glutathione-S-transferase-pi strongly and selectively blocks mitotic signaling by oncogenic ras-p21.

Oncogenic ras-p21 directly activates jun-N-terminal kinase (JNK) and its substrate, jun as a unique step on its mitogenic signal transduction pathway. This activation is blocked by the specific JNK-jun inhibitor, glutathione-S-transferase-pi (GST-pi). Four domains of GST-pi have been implicated in this regulatory function: 34-50, 99-121, 165-182, and 194-201. The 34-50 domain is unique in that it does not affect GST-pi binding to JNK-jun but blocks jun phosphorylation by JNK. We now find that it completely blocks oncogenic (Val 12-) ras-p21-induced oocyte maturation but has no effect on insulin-induced oocyte maturation. Because the latter process requires activation of wild-type ras-p21, this peptide appears to be specific for inhibiting only the oncogenic form of ras-p21, suggesting its use in treating ras-induced tumors.

Effector peptides from glutathione-S-transferase-pi affect the activation of jun by jun-N-terminal kinase.

We have previously found that the pi-isozyme of glutathione-S-transferase (GST-pi) is a strong and selective inhibitor of the phosphorylation of the transcriptional activating protein jun by its activating kinase, jun-N-terminal kinase (JNK). We further performed molecular dynamics calculations on the 3-dimensional structure of GST-pi free and bound to an inhibitor that blocks its ability to inhibit the JNK-jun activation. We thus identified 4 putative domains that may be involved in the interaction between GST-pi and the JNK-jun complex: residues 34-50, 99-121, 165-182 (with 2 overlapping sub-domains 165-175 and 169-182), and 194-201. We have synthesized each of these domains and tested them for their abilities to affect the GST-JNK-jun system, first in a cell-free system. We find that peptides corresponding to residues 99-121 and 194-201 strongly inhibit the binding of GST to the JNK-jun complex but do not inhibit JNK-induced phosphorylation of jun, while peptides corresponding to residues 34-50 and 165-182 do not inhibit GST binding but, except for the 165-175 subdomain peptide, strongly inhibit jun phosphorylation. A control peptide, X13, had no effect on either process. Peptide effects on jun phosphorylation appear to be selective for the JNK-jun system since the 34-50 peptide has no effect on other kinase systems (eg, casein kinase, MAP kinase). Three of the domain peptides, 34-50, 165-175, and 194-201 have been attached on their carboxyl-terminal ends to a penetratin sequence, enabling transmembrane transport into cells, and have been introduced into human astrocytes in which JNK was activated with anisomycin. We find that the 34-50-penetratin peptide strongly inhibits intracellular jun phosphorylation while the 194-201-penetratin peptide has no effect; the 165-175-penetratin peptide has a weak effect on this process. Thus, the effects in cells parallel those in the cell-free system. We conclude that all putative domains, identified in our prior structural studies, appear to interact with the JNK-jun complex. The 34-50 peptide may be useful in selectively blocking uncontrolled mitogenic signaling involving the JNK-jun pathway and may be a potential agent for blocking oncogenic ras-p21-induced cell transformation.

Small, highly structured RNAs participate in the conversion of human recombinant PrP(Sen) to PrP(Res) in vitro.

We have identified a small, highly structured (shs)RNA that binds human recombinant prion protein (hrPrP) with high affinity and specificity under physiological conditions (e.g. 10% bovine calf serum (BCS), neutral pH, nanomolar concentrations of RNA and hrPrP). We also demonstrate the ability of this shsRNA to form highly stable nucleoprotein complexes with hrPrP and cellular PrP (PrP(C)) from various cell extracts and mammalian brain homogenates. The apparent mass of the nucleoprotein complex is dependent on the molar ratio of hrPrP to RNA during complex formation. The hrPrP in these complexes acquires resistance to degradation by Proteinase K (PK). Other shsRNAs, however, under identical conditions, neither form stable complexes with hrPrP nor do they induce resistance to PK digestion. We also demonstrate that the RNAs in these nucleoprotein complexes become resistant to ribonuclease A hydrolysis. These interactions between shsRNAs and hrPrP suggest possible roles of RNAs in the modulation of PrP structure and perhaps disease development. ShsRNAs that bind to hrPrP with high affinity and induce resistance to PK digestion can be used to develop molecular biology assays for the screening of compounds associated with PrP structure transformation or for drugs that inhibit this process.

Concentration and removal of prion proteins from biological solutions.

The pathogenesis of prion diseases is characterized by the accumulation of amyloid-like rods or scrapie-associated fibrils. The major protein component of scrapie-associated fibrils is an abnormally folded isoform of the normal cellular prion protein (PrP(C)) that is resistant to digestion by proteinase K and is referred to as PrP(Sc). Purified human recombinant (hr PrP) was used to characterize the binding of a set of RNAs with affinity to PrP proteins. We report here that hr PrP has two RNA-binding activities at physiological pH. One activity is capable of binding all of the screened RNAs with high affinity, whereas the other activity can bind only to a subset of the RNAs with high affinity in the presence of non-specific competitor RNAs. A novel RNA belonging to the latter class, RQ11+12, bound to hr PrP with high affinity in the presence of vast molar excesses of competing RNAs. Beads impregnated with the RQ11+12 RNA were used to construct a filtration column. The column efficiently bound hr PrP and native PrP(C) from serum and urine. Importantly, the filtration device was also capable of binding proteinase K-treated PrP(Sc) from serum and urine. The level of sensitivity of detection of PrP by standard Western blotting was increased at least 1000-fold by first concentrating PrP from solution with the filtration column.