- Email: [email protected]
Protein Kinase C-β as a Therapeutic Target in Breast Cancer
Protein Kinase C- as a Therapeutic Target in Breast Cancer George W. Sledge, Jr and Yesim Gökmen-Polar Combining existing breast cancer therapies with novel agents that interfere with major signaling pathways is a promising approach. Targeting protein kinase C (PKC)- may serve as an attractive candidate in this regard for the following reasons: first, PKC- II (a splice variant of PKC-) has been implicated in tumorigenesis in human and rodent models. Second, PKC-, mainly PKC-II, is the predominant mediator of vascular endothelial growth factor-induced endothelial cell proliferation, which is a well-known stimulator of tumor angiogenesis and growth in breast cancer. There is increasing evidence that PKC-selective inhibitors are effective in both preclinical and clinical trials. Enzastaurin, a potent inhibitor of PKC-, suppresses both tumor growth and tumor-induced angiogenesis in human tumor xenografts. Phase II trials of enzastaurin in recurrent high-grade gliomas and lymphomas have shown promising results. A similar compound, ruboxistaurin, is also under investigation in clinical trials for diabetic complications. This review focuses on the rationale for using PKC- as a therapeutic target at both the preclinical and clinical levels in breast cancer. Semin Oncol 33(suppl 9):S15-S18 © 2006 Elsevier Inc. All rights reserved.
P
rotein kinase C (PKC) is a family of at least 12 distinct serine/threonine kinases that are involved in diverse cellular functions including cell proliferation, differentiation, apoptosis, tumorigenesis, angiogenesis, and drug resistance.1-3 Individual PKC isozymes have distinct cellular functions based on their differences in tissue expression, subcellular localization, and activator/substrate specificity.4-7 The role of PKC isozymes in cancer has been reviewed in depth by Fields and Gustafson.1 Therefore, it is logical to develop isozyme-specific inhibitors, with the potential for targeting specific intracellular pathways, rather than broadrange PKC inhibitors. This review discusses the rationale underlying therapeutic targeting of PKC- for cancer in general and for breast cancer in particular.
The Role of PKC- in Cancer The PKC- gene codes for two distinct proteins generated by alternative splicing: PKC-I and PKC-II, which differ in the last 50 amino acids.8 Several studies indicate that these two
Departments of Medicine and Pathology, Indiana University Cancer Center, Indianapolis, IN. Dr Sledge’s work is supported in part by a grant from the Breast Cancer Research Foundation and the Walther Medical Foundation. Address reprint requests to George W. Sledge, Jr, MD, Departments of Medicine and Pathology, Indiana University Cancer Center, RT-473, Indianapolis, IN 46220. E-mail: [email protected]
0093-7754/06/$-see front matter © 2006 Elsevier Inc. All rights reserved. doi:10.1053/j.seminoncol.2006.03.019
splice variants participate in opposing cellular functions: PKC-II is involved in cellular proliferation, whereas PKC-I is associated with differentiation.7,9,10 The role of PKC-II has been well documented in proliferation and tumorigenesis of colorectal carcinomas.9,11 Murray et al9 showed that overexpression of PKC-II in the colonic epithelium resulted in hyperproliferation and increased susceptibility to carcinogen-induced colon carcinogenesis. Expression of PKC-II increases dramatically early in the colon carcinogenic process.11 Furthermore, PKC-II also induced an invasive phenotype in rat intestinal epithelial cells.12 PKC-I, on the other hand, has been shown to be down-regulated in colonic neoplasms.13,14 A decrease in PKC-I levels has also been observed in the adenomatous polyposis coli multiple intestinal neoplasia (APCmin) mouse colon carcinogenesis model.15 Other studies have also emphasized the contribution of PKC- to the malignant progression of diffuse, large, B-cell lymphomas (DLBCLs)16 and gliomas.17 In DLBCL especially, patient survival was inversely correlated with high levels of PKC- expression.16 Treatment of DLBCL cells with the PKC--specific inhibitor LY379196 induced apoptosis in PKC- overexpressing DLBCL cells.18
PKC- in Breast Cancer Several studies have investigated the expression of PKC isozymes and activity in breast cancer. PKC activity was elevated in malignant breast tumors relative to surrounding norS15
S16 mal tissue,19,20 and was correlated with the more aggressive estrogen receptor-negative phenotype.21,22 However, these early studies failed to differentiate between PKC isozymes and their subtypes. Among the PKC isozymes, PKC-␦ has been shown to be involved in mammary tumor metastasis,23,24 and PKC-␣ has been implicated in malignant transformation and tumor cell proliferation of the breast.25 Despite these results, breast cancer trials on the role of PKC- or any other PKC isozymes in relation to PKC- are not well addressed. Most of the available studies of PKC- in breast cancer relate to in vitro cell line studies, typically with a limited number of human breast cancer cell lines. In one in vitro study, stable overexpression of PKC-␣ significantly increased the endogenous expression of PKC-, accompanied by decreases in levels of PKC- and -␦. This model also showed increased proliferation and anchorage-independent growth, alterations in cellular morphology characterized by loss of epithelial appearance with a marked increase in vimentin expression, decreased estrogen receptor messenger RNA and estrogen-dependent gene expression, and enhanced tumorigenesis and metastasis when injected into nude mice.26 Another study by Morse-Gaudio et al27 confirmed the association of PKC- with MCF-7 cells overexpressing PKC-␣ and showed that conventional PKC isozymes are associated with the metastatic phenotype in breast cancer cells. In contrast, a separate preclinical study showed that overexpression of PKC-␣ and - (PKC-I) induced a less-aggressive phenotype, which was characterized by reduced in vitro invasiveness and markedly diminished tumor formation and growth.28 Improved anti-estrogen resistance in mammary tumor cells has also been associated with MCF-7 cells overexpressing active PKC-␦.29 These discrepancies can be explained in two ways. First, it is important to analyze the expression of each PKC- splice variant to assess its potential role in breast cancer, because the expression of PKC-I and PKC-II may be differentially regulated.30 Second, overexpression of one PKC isozyme may alter expression of other PKC isozymes. Therefore, it is necessary to redefine the role of PKC- and its associated PKC isozymes in breast cancer. To date, no large-scale studies of the relationship between PKC isozymes and clinical outcome have been performed. Further studies are underway to analyze human breast cancer specimens for PKC-II expression.
PKC- and Angiogenesis Vascular endothelial growth factor (VEGF) is one of a number of genes associated with angiogenesis, which is a process necessary for tumor growth. VEGF acts via kinase insert domain-containing receptor/VEGF receptor (VEGFR)-2 and subsequent phospholipase C (PLC)-␥ tyrosine phosphorylation to promote activation of PKC- in endothelial cells.31 PKC- activation, in turn, induces the activation of the Raf/ mitogen-activated protein kinase (MAPK) and extracellularsignal-regulated kinase (ERK) cascade and subsequent endothelial cell proliferation (Fig 1).32,33 Yoshiji et al34 reported that PKC- inhibition reduced tumor growth by decreasing
G.W. Sledge, Jr and Y. Gökmen-Polar
Figure 1 PKC- in VEGF signaling. Binding of VEGF to its receptor (KDR/VEGFR-2) initiates the tyrosine phosphorylation and activation of phospholipase-␥ resulting in the generation of DAG, IP3, and Ca2⫹ mobilization, and subsequent activation of PKC-. Further activation of Raf, MEK, and ERK leads to both mitogenesis and cPLA2 activation, and generation of PGs. Signaling by Ca2⫹ also results in the production of long-term PGs through the PP2B, the transcription NFAT, and COX-2 induction. Abbreviations: COX-2, cyclooxygenase-2; cPLA2, cytosolic phospholipase A2; DAG, diacylglycerol; ERK, extracellular signal-regulated kinase; IP3, inositol 1,4,5-trisphosphate; KDR, kinase insert domain-containing receptor; MEK, mitogen-activated protein kinase; NFAT, nuclear factor of activated T-cells; P, phosphate; PGs, prostanoids; PKC, protein kinase C; PLC-␥, phospholipase C-␥; PP2B, serine/threonine phosphatase; VEGF, vascular endothelial growth factor; VEGFR, VEGF receptor.
VEGF-dependent MAPK activation, suggesting the involvement of PKC- in VEGF-induced tumor development and angiogenesis. The role of PKC- in the VEGF-induced Akt pathway is still not clear. VEGF may activate phosphatidylinositol-3-kinase and PLC-␥ via different pathways.31,32 The PLC-␥/PKC/ERK pathway also mediates VEGF-induced activation of cytosolic phospholipase A2 and results in generation of cyclooxygenase-derived prostanoids.33 Ca2⫹ also contributes to the activation of the protein serine/threonine phosphatase 2B, which activates transcription factor nuclear factor of activated T cells, and leads to the induction of cyclooxygenase-2, which further activates long-term prostanoid production.33 Recent data from the E2100 first-line metastatic breast cancer trial35 studying the combination of paclitaxel plus bevacizumab showed that the addition of a VEGF-targeted agent to a standard chemotherapeutic agent could result in a significant improvement in progression-free and overall survival. This proof-of-concept trial may provide a foundation for therapeutic targeting of angiogenesis in breast cancer, and
PKC- as a target in breast cancer raises the question of whether other therapeutic approaches to targeting angiogenesis might be beneficial in breast cancer. To date, there are no preclinical or clinical data examining the combination of VEGF and PKC- targeting. It seems reasonable to examine such an “upstream/downstream” approach, both in the laboratory and the clinic. Plans for both areas are being investigated.
Therapeutic Targeting of PKC- PKC- clearly represents a potential angiogenesis therapeutic target. Indeed, the PKC--specific inhibitor LY379196 has been shown to induce apoptosis in DLBCL cells overexpressing PKC-.18 Studies of LY379196, as well as LY333531, another PKC- inhibitor, have been reviewed by Goekjian and Jirousek.2 One of the most promising PKC- inhibitors, enzastaurin, is an acyclic bisindolylmaleimide that competes with the adenosine triphosphate binding site of PKC, preventing substrate phosphorylation. While it is capable of inhibiting several members of the PKC family, it is most potent against PKC- (inhibitor concentration 90 ⫽ .069 mol/L).36 It is relatively inactive against other kinases, including tyrosine kinases. Enzastaurin is a more potent inhibitor of endothelial cell proliferation than of tumor cell proliferation, at least for some cancer cell lines in vitro.37 This, of course, raises the possibility that its effects will be mediated predominantly via an anti-angiogenic mechanism, although this remains to be demonstrated in the clinic. In preclinical models, enzastaurin inhibits tumor growth in vitro and in vivo in numerous human tumor models, and has significant anti-angiogenic activity in vitro and in vivo. In vivo, PKC- inhibition with enzastaurin has been shown to inhibit VEGF and basic fibroblast growth factor-stimulated angiogenesis in the rat corneal micropocket assay, a standard angiogenesis assay.37 In some, but not all, tumor-bearing mouse models, PKC- inhibition decreases plasma VEGF levels after 5 to 7 days of treatment.38 In several murine model systems, including the MX-1 human breast cancer xenograft model system, PKC- inhibition results in decreased intratumoral angiogenesis as measured by decreased microvessel density.39 Enzastaurin has entered phase I trials, both as monotherapy40 and in combination with gemcitabine and cisplatin.41 In both trials the agent was well tolerated, with promising initial evidence of activity. More recently, enzastaurin has entered phase II trials for treatment of glioma and lymphoma, and colon, prostate, non–small cell lung, ovarian, and pancreatic cancers, as well as chronic lymphocytic leukemia. In gliomas, the agent showed promising early evidence of activity, with responses observed in heavily pretreated patients.42 In a group of 55 patients with heavily pretreated DLBCL, enzastaurin therapy produced prolonged disease stabilization and occasional remissions.43 To date, there have been no trials of enzastaurin in metastatic breast cancer. In preclinical models, enzastaurin is growth inhibitory in vitro against some (MCF-7, NCI/ADR-RES, and MDA-MB-
S17 435), but not all (HS-578T, BT-549, and T-47D), breast cancer cell lines in the NCI 60 cell-line panel.39 In a preclinical MX-1 xenograft model of human breast cancer, Teicher et al39 showed that the combination of enzastaurin with either paclitaxel or carboplatin resulted in significantly greater anti-tumor activity than either agent alone.38 At present, no preclinical research has been conducted combining this agent with either human epidermal growth factor receptor-2or estrogen-receptor-targeted therapies. A phase II clinical trial of enzastaurin as monotherapy for advanced breast cancer will begin in the near future.
Conclusion PKC- represents an under-explored therapeutic target in breast cancer. The growing evidence for the importance of angiogenesis as a therapeutic target in breast cancer and its modulation via PKC- suggest the promise of targeting this molecule. New data should emerge in the near future showing the biologic importance of PKC- in clinical breast cancer, and will help to determine whether specific agents targeting PKC- (such as enzastaurin) will offer benefit to patients with this disease.
References 1. Fields AP, Gustafson WC: Protein kinase C in disease, in Newton AC (ed): Methods in Molecular Biology, vol 233: Protein kinase C protocols. Totowa, NJ, Humana Press Inc, 2003, pp 519-537 2. Goekjian PG, Jirousek MR: Protein kinase C inhibitors as novel anticancer drugs. Expert Opin Invest Drugs 10:2117-2140, 2001 3. Hofmann J: Protein kinase C isozymes as potential targets for anticancer therapy. Curr Cancer Drug Targets 4:125-146, 2004 4. Nishizuka Y: The molecular heterogeneity of protein kinase C and its implications for cellular regulation. Nature 334:661-665, 1988 5. Hug H, Sarre TF: Protein kinase C isoenzymes: Divergence in signal transduction? Biochem J 291:329-343, 1993 6. Hocevar BA, Morrow DM, Tykocinski ML, et al: Protein kinase C isotypes in human erythroleukemia cell proliferation and differentiation. J Cell Sci 101:671-679, 1992 7. Murray NR, Baumgardner GP, Burns DJ, et al: Protein kinase C isotypes in human erythroleukemia (K562) cell proliferation and differentiation. Evidence that II protein kinase C is required for proliferation. J Biol Chem 268:15847-15853, 1993 8. Ono Y, Kikkawa U, Ogita K, et al: Expression and properties of two types of protein kinase C: Alternative splicing from a single gene. Science 236:1116-1120, 1987 9. Murray NR, Davidson LA, Chapkin RS, et al: Overexpression of protein kinase C II induces colonic hyperproliferation and increased sensitivity to colon carcinogenesis. J Cell Biol 145:699-711, 1999 10. Black JD: Protein kinase C isozymes in colon carcinogenesis: Guilt by omission. Gastroenterology 120:1868-1872, 2001 11. Gökmen-Polar Y, Murray NR, Velasco MA, et al: Elevated protein kinase C beta II is an early promotive event in colon carcinogenesis. Cancer Res 61:1375-1381, 2001 12. Zhang J, Anastasiadis PZ, Liu Y, et al: Protein kinase C (PKC) II induces cell invasion through a Ras/Mek-, PKCiota/Rac 1-dependent signaling pathway. J Biol Chem 279:22118-22123, 2004 13. Suga K, Sugimoto I, Ito H, et al: Down-regulation of protein kinase C alpha detected in human colorectal cancer. Biochem Mol Biol Int 44: 523-528, 1998 14. Davidson LA, Brown RE, Chang WC, et al: Morphodensitometric analysis of protein kinase C beta (II) expression in rat colon: Modulation by diet and relation to in situ cell proliferation and apoptosis. Carcinogenesis 21:1513-1519, 2000
S18 15. Klein IK, Ritland SR, Burgart LJ, et al: Adenoma-specific alterations of protein kinase C expression in Apc(MIN) mice. Cancer Res 60:20772080, 2000 16. Shipp MA, Ross KN, Tamayo P, et al: Diffuse large B-cell lymphoma outcome prediction by gene-expression profiling and supervised machine learning. Nat Med 8:68-74, 2002 17. da Rocha AB, Mans DR, Regner A, et al: Targeting protein kinase C: New therapeutic opportunities against high-grade malignant gliomas? Oncologist 7:17-33, 2002 18. Su TT, Guo B, Kawakami Y, et al: PKC-beta controls I kappa B kinase lipid raft recruitment and activation in response to BCR signaling. Nat Immunol 3:780-786, 2002 19. O’Brian CA, Vogel VG, Singletary SE, et al: Elevated protein kinase C expression in human breast tumor biopsies relative to normal breast tissue. Cancer Res 49:3215-3217, 1989 20. Gordge PC, Hulme MJ, Clegg RA, et al: Elevation of protein kinase A and protein kinase C activities in malignant as compared with normal human breast tissue. Eur J Cancer 32A:2120-2126, 1996 21. Borner C, Wyss R, Regazzi R, et al: Immunological quantitation of phospholipid/Ca2⫹-dependent protein kinase of human mammary carcinoma cells: Inverse relationship to estrogen receptors. Int J Cancer 40:344-348, 1987 22. Lee SA, Karaszkiewicz JW, Anderson WB: Elevated level of nuclear protein kinase C in multidrug-resistant MCF-7 human breast carcinoma cells. Cancer Res 52:3750-3759, 1992 23. Kiley SC, Clark KJ, Duddy SK, et al: Increased protein kinase C␦ in mammary tumor cells: relationship to transformation and metastasic progression. Oncogene 18:6748-6757, 1999 24. Kiley SC, Clark KJ, Goodnough M, et al: Protein Kinase C␦ involvement in mammary tumor cell metastasis. Cancer Res 59:3230-3238, 1999 25. Lahn M, Köhler G, Sundell K, et al: Protein kinase C alpha expression in breast and ovarian cancer. Oncology 67:1-10, 2004 26. Ways DK, Kukoly CA, deVente J, et al: MCF-7 breast cancer cells transfected with protein kinase C-alpha exhibit altered expression of other protein kinase C isoforms and display a more aggressive neoplastic phenotype. J Clin Invest 95:1906-1915, 1995 27. Morse-Gaudio M, Connolly JM, Rose DP: Protein kinase C and its isoforms in human breast cancer cells: Relationship to the invasive phenotype. Int J Oncol 12:1349-1354, 1998 28. Manni A, Buckwalter E, Etindi R, et al: Induction of a less aggressive breast cancer phenotype by protein kinase C-␣ and -overexpression. Cell Growth Differ 7:1187-1198, 1996 29. Nabha SM, Glaros S, Hong M, et al: Upregulation of PKC␦ contributes to antiestrogen resistance in mammary tumor cells. Oncogene 24: 3166-3176, 2005
G.W. Sledge, Jr and Y. Gökmen-Polar 30. Chalfant CE, Mishak H, Watson JE, et al: Regulation of alternative splicing of protein kinase C beta by insulin. J Biol Chem 270:1332613332, 1995 31. Xia P, Aiello LP, Ishii H, et al: Characterization of vascular endothelial growth factor’s effect on the activation of protein kinase C, its isoforms, and endothelial cell growth. J Clin Invest 98:2018-2026, 1996 32. Takahashi T, Ueno H, Shibuya M: VEGF activates protein kinase Cdependent, but Ras independent Raf-MEK-MAP kinase pathway for DNA synthesis in primary endothelial cells. Oncogene 18:2221-2230, 1999 33. Zachary I: VEGF signaling: integration and multi-tasking in endothelial cell biology. Biochem Soc Trans 6:1171-1177, 2003 34. Yoshiji H, Kuriyama S, Ways DK, et al: Protein kinase C lies on the signaling pathway for vascular endothelial growth factor-mediated tumor development and angiogenesis. Cancer Res 59:4413-4418, 1999 35. Miller KD, Wang M, Gralow JD, et al: E2100: A randomized phase III trial of paclitaxel versus paclitaxel plus bevacizumab as first-line therapy for locally recurrent or metastatic breast cancer. Presented at the 41st Annual Meeting of the American Society of Clinical Oncology, Orlando, FL, May 13-17, 2004 36. Graff JR, McNulty AM, Hanna KR, et al: The protein kinase cb-selective inhibitor, enzastaurin (LY317615.HCL), supressess signaling through the Akt pathway, induces apoptosis, and suppresses growth of human colon cancer and glioblastoma xenografts. Cancer Res 65:7462-7469, 2005 37. Teicher BA, Alvarez E, Menon K, et al: Antiangiogenic effects of a protein kinase C-selective small molecule. Cancer Chemother Pharmacol 49:69-77, 2002 38. Keyes KA, Mann L, Sherman M, et al: LY317615 decreases plasma VEGF levels in human tumor xenograft-bearing mice. Cancer Chemother Pharmacol 53:133-140, 2004 39. Teicher BA, Menon K, Alvarez E, et al: Antiangiogenic and antitumor effects of a protein kinase C beta inhibitor in human breast cancer and ovarian cancer xenografts. Invest New Drugs 20:241-251, 2002 40. Herbst RS, Thornton DE, Kies MS, et al: Phase 1 study of LY317615, a protein kinase Cb inhibitor. Proc Am Soc Clin Oncol 21:326, 2002 (abstr) 41. Rademaker-Lakhai JM: Phase I and pharmacologic study of enzastaurin HCl, gemcitabine and cisplatin. Proc Am Soc Clin Oncol 24:3129, 2004 (abstr) 42. Fine HA, Royce KM, Draper D, et al: Results from phase II trial of enzastaurin (LY317615) in patients with recurrent high grade gliomas. Proc Am Soc Clin Oncol 23:1504, 2005 (abstr) 43. Robertson M, Kahl B, Vose J, et al: A phase II study of enzastaurin, a protein kinase C- (PKC) inhibitor, in the treatment of relapsed diffuse large B-cell lymphoma (DLBCL). Blood 106:934, 2005 (abstr)
P
rotein kinase C (PKC) is a family of at least 12 distinct serine/threonine kinases that are involved in diverse cellular functions including cell proliferation, differentiation, apoptosis, tumorigenesis, angiogenesis, and drug resistance.1-3 Individual PKC isozymes have distinct cellular functions based on their differences in tissue expression, subcellular localization, and activator/substrate specificity.4-7 The role of PKC isozymes in cancer has been reviewed in depth by Fields and Gustafson.1 Therefore, it is logical to develop isozyme-specific inhibitors, with the potential for targeting specific intracellular pathways, rather than broadrange PKC inhibitors. This review discusses the rationale underlying therapeutic targeting of PKC- for cancer in general and for breast cancer in particular.
The Role of PKC- in Cancer The PKC- gene codes for two distinct proteins generated by alternative splicing: PKC-I and PKC-II, which differ in the last 50 amino acids.8 Several studies indicate that these two
Departments of Medicine and Pathology, Indiana University Cancer Center, Indianapolis, IN. Dr Sledge’s work is supported in part by a grant from the Breast Cancer Research Foundation and the Walther Medical Foundation. Address reprint requests to George W. Sledge, Jr, MD, Departments of Medicine and Pathology, Indiana University Cancer Center, RT-473, Indianapolis, IN 46220. E-mail: [email protected]
0093-7754/06/$-see front matter © 2006 Elsevier Inc. All rights reserved. doi:10.1053/j.seminoncol.2006.03.019
splice variants participate in opposing cellular functions: PKC-II is involved in cellular proliferation, whereas PKC-I is associated with differentiation.7,9,10 The role of PKC-II has been well documented in proliferation and tumorigenesis of colorectal carcinomas.9,11 Murray et al9 showed that overexpression of PKC-II in the colonic epithelium resulted in hyperproliferation and increased susceptibility to carcinogen-induced colon carcinogenesis. Expression of PKC-II increases dramatically early in the colon carcinogenic process.11 Furthermore, PKC-II also induced an invasive phenotype in rat intestinal epithelial cells.12 PKC-I, on the other hand, has been shown to be down-regulated in colonic neoplasms.13,14 A decrease in PKC-I levels has also been observed in the adenomatous polyposis coli multiple intestinal neoplasia (APCmin) mouse colon carcinogenesis model.15 Other studies have also emphasized the contribution of PKC- to the malignant progression of diffuse, large, B-cell lymphomas (DLBCLs)16 and gliomas.17 In DLBCL especially, patient survival was inversely correlated with high levels of PKC- expression.16 Treatment of DLBCL cells with the PKC--specific inhibitor LY379196 induced apoptosis in PKC- overexpressing DLBCL cells.18
PKC- in Breast Cancer Several studies have investigated the expression of PKC isozymes and activity in breast cancer. PKC activity was elevated in malignant breast tumors relative to surrounding norS15
S16 mal tissue,19,20 and was correlated with the more aggressive estrogen receptor-negative phenotype.21,22 However, these early studies failed to differentiate between PKC isozymes and their subtypes. Among the PKC isozymes, PKC-␦ has been shown to be involved in mammary tumor metastasis,23,24 and PKC-␣ has been implicated in malignant transformation and tumor cell proliferation of the breast.25 Despite these results, breast cancer trials on the role of PKC- or any other PKC isozymes in relation to PKC- are not well addressed. Most of the available studies of PKC- in breast cancer relate to in vitro cell line studies, typically with a limited number of human breast cancer cell lines. In one in vitro study, stable overexpression of PKC-␣ significantly increased the endogenous expression of PKC-, accompanied by decreases in levels of PKC- and -␦. This model also showed increased proliferation and anchorage-independent growth, alterations in cellular morphology characterized by loss of epithelial appearance with a marked increase in vimentin expression, decreased estrogen receptor messenger RNA and estrogen-dependent gene expression, and enhanced tumorigenesis and metastasis when injected into nude mice.26 Another study by Morse-Gaudio et al27 confirmed the association of PKC- with MCF-7 cells overexpressing PKC-␣ and showed that conventional PKC isozymes are associated with the metastatic phenotype in breast cancer cells. In contrast, a separate preclinical study showed that overexpression of PKC-␣ and - (PKC-I) induced a less-aggressive phenotype, which was characterized by reduced in vitro invasiveness and markedly diminished tumor formation and growth.28 Improved anti-estrogen resistance in mammary tumor cells has also been associated with MCF-7 cells overexpressing active PKC-␦.29 These discrepancies can be explained in two ways. First, it is important to analyze the expression of each PKC- splice variant to assess its potential role in breast cancer, because the expression of PKC-I and PKC-II may be differentially regulated.30 Second, overexpression of one PKC isozyme may alter expression of other PKC isozymes. Therefore, it is necessary to redefine the role of PKC- and its associated PKC isozymes in breast cancer. To date, no large-scale studies of the relationship between PKC isozymes and clinical outcome have been performed. Further studies are underway to analyze human breast cancer specimens for PKC-II expression.
PKC- and Angiogenesis Vascular endothelial growth factor (VEGF) is one of a number of genes associated with angiogenesis, which is a process necessary for tumor growth. VEGF acts via kinase insert domain-containing receptor/VEGF receptor (VEGFR)-2 and subsequent phospholipase C (PLC)-␥ tyrosine phosphorylation to promote activation of PKC- in endothelial cells.31 PKC- activation, in turn, induces the activation of the Raf/ mitogen-activated protein kinase (MAPK) and extracellularsignal-regulated kinase (ERK) cascade and subsequent endothelial cell proliferation (Fig 1).32,33 Yoshiji et al34 reported that PKC- inhibition reduced tumor growth by decreasing
G.W. Sledge, Jr and Y. Gökmen-Polar
Figure 1 PKC- in VEGF signaling. Binding of VEGF to its receptor (KDR/VEGFR-2) initiates the tyrosine phosphorylation and activation of phospholipase-␥ resulting in the generation of DAG, IP3, and Ca2⫹ mobilization, and subsequent activation of PKC-. Further activation of Raf, MEK, and ERK leads to both mitogenesis and cPLA2 activation, and generation of PGs. Signaling by Ca2⫹ also results in the production of long-term PGs through the PP2B, the transcription NFAT, and COX-2 induction. Abbreviations: COX-2, cyclooxygenase-2; cPLA2, cytosolic phospholipase A2; DAG, diacylglycerol; ERK, extracellular signal-regulated kinase; IP3, inositol 1,4,5-trisphosphate; KDR, kinase insert domain-containing receptor; MEK, mitogen-activated protein kinase; NFAT, nuclear factor of activated T-cells; P, phosphate; PGs, prostanoids; PKC, protein kinase C; PLC-␥, phospholipase C-␥; PP2B, serine/threonine phosphatase; VEGF, vascular endothelial growth factor; VEGFR, VEGF receptor.
VEGF-dependent MAPK activation, suggesting the involvement of PKC- in VEGF-induced tumor development and angiogenesis. The role of PKC- in the VEGF-induced Akt pathway is still not clear. VEGF may activate phosphatidylinositol-3-kinase and PLC-␥ via different pathways.31,32 The PLC-␥/PKC/ERK pathway also mediates VEGF-induced activation of cytosolic phospholipase A2 and results in generation of cyclooxygenase-derived prostanoids.33 Ca2⫹ also contributes to the activation of the protein serine/threonine phosphatase 2B, which activates transcription factor nuclear factor of activated T cells, and leads to the induction of cyclooxygenase-2, which further activates long-term prostanoid production.33 Recent data from the E2100 first-line metastatic breast cancer trial35 studying the combination of paclitaxel plus bevacizumab showed that the addition of a VEGF-targeted agent to a standard chemotherapeutic agent could result in a significant improvement in progression-free and overall survival. This proof-of-concept trial may provide a foundation for therapeutic targeting of angiogenesis in breast cancer, and
PKC- as a target in breast cancer raises the question of whether other therapeutic approaches to targeting angiogenesis might be beneficial in breast cancer. To date, there are no preclinical or clinical data examining the combination of VEGF and PKC- targeting. It seems reasonable to examine such an “upstream/downstream” approach, both in the laboratory and the clinic. Plans for both areas are being investigated.
Therapeutic Targeting of PKC- PKC- clearly represents a potential angiogenesis therapeutic target. Indeed, the PKC--specific inhibitor LY379196 has been shown to induce apoptosis in DLBCL cells overexpressing PKC-.18 Studies of LY379196, as well as LY333531, another PKC- inhibitor, have been reviewed by Goekjian and Jirousek.2 One of the most promising PKC- inhibitors, enzastaurin, is an acyclic bisindolylmaleimide that competes with the adenosine triphosphate binding site of PKC, preventing substrate phosphorylation. While it is capable of inhibiting several members of the PKC family, it is most potent against PKC- (inhibitor concentration 90 ⫽ .069 mol/L).36 It is relatively inactive against other kinases, including tyrosine kinases. Enzastaurin is a more potent inhibitor of endothelial cell proliferation than of tumor cell proliferation, at least for some cancer cell lines in vitro.37 This, of course, raises the possibility that its effects will be mediated predominantly via an anti-angiogenic mechanism, although this remains to be demonstrated in the clinic. In preclinical models, enzastaurin inhibits tumor growth in vitro and in vivo in numerous human tumor models, and has significant anti-angiogenic activity in vitro and in vivo. In vivo, PKC- inhibition with enzastaurin has been shown to inhibit VEGF and basic fibroblast growth factor-stimulated angiogenesis in the rat corneal micropocket assay, a standard angiogenesis assay.37 In some, but not all, tumor-bearing mouse models, PKC- inhibition decreases plasma VEGF levels after 5 to 7 days of treatment.38 In several murine model systems, including the MX-1 human breast cancer xenograft model system, PKC- inhibition results in decreased intratumoral angiogenesis as measured by decreased microvessel density.39 Enzastaurin has entered phase I trials, both as monotherapy40 and in combination with gemcitabine and cisplatin.41 In both trials the agent was well tolerated, with promising initial evidence of activity. More recently, enzastaurin has entered phase II trials for treatment of glioma and lymphoma, and colon, prostate, non–small cell lung, ovarian, and pancreatic cancers, as well as chronic lymphocytic leukemia. In gliomas, the agent showed promising early evidence of activity, with responses observed in heavily pretreated patients.42 In a group of 55 patients with heavily pretreated DLBCL, enzastaurin therapy produced prolonged disease stabilization and occasional remissions.43 To date, there have been no trials of enzastaurin in metastatic breast cancer. In preclinical models, enzastaurin is growth inhibitory in vitro against some (MCF-7, NCI/ADR-RES, and MDA-MB-
S17 435), but not all (HS-578T, BT-549, and T-47D), breast cancer cell lines in the NCI 60 cell-line panel.39 In a preclinical MX-1 xenograft model of human breast cancer, Teicher et al39 showed that the combination of enzastaurin with either paclitaxel or carboplatin resulted in significantly greater anti-tumor activity than either agent alone.38 At present, no preclinical research has been conducted combining this agent with either human epidermal growth factor receptor-2or estrogen-receptor-targeted therapies. A phase II clinical trial of enzastaurin as monotherapy for advanced breast cancer will begin in the near future.
Conclusion PKC- represents an under-explored therapeutic target in breast cancer. The growing evidence for the importance of angiogenesis as a therapeutic target in breast cancer and its modulation via PKC- suggest the promise of targeting this molecule. New data should emerge in the near future showing the biologic importance of PKC- in clinical breast cancer, and will help to determine whether specific agents targeting PKC- (such as enzastaurin) will offer benefit to patients with this disease.
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