Yucheng Tang

An adenoviral vector cancer vaccine that delivers a tumor-associated antigen/CD40-ligand fusion protein to dendritic cells

To develop a method to overcome the anergy that exists in tumor hosts to cancer, we have designed an adenoviral vector for the in vivo activation and tumor antigen loading of dendritic cells. This adenoviral vector encodes a fusion protein composed of an amino-terminal tumor-associated antigen fragment fused to the CD40 ligand (CD40L). Subcutaneous injection of an adenoviral vector encoding a fusion protein of the human papillomavirus E7 foreign antigen linked to the CD40L generates CD8+ T cell-dependent immunoresistance to the growth of the E7-positive syngeneic TC-1 cancer cells in C57BL/6 mice for up to 1 year. We also studied the s.c. injection of a vector carrying the gene for the human MUC-1 (hMUC-1) self-antigen fused to the CD40L. When this vector was injected into hMUC-1.Tg mice, which are transgenic for the hMUC-1 antigen, the growth of syngeneic hMUC-1-positive LL1/LL2hMUC-1 mouse cancer cells was suppressed in 100% of the injected animals. The hMUC-1.Tg mice are anergic to the hMUC-1 antigen before the injection of the vector. These experimental results show that it is possible to use vector injection to activate a long-lasting cellular immune response against self-antigens in anergic animals. The vector-mediated in vivo activation, and tumor-associated antigen loading of dendritic cells does not require additional cytokine boosting to induce the immune response against the tumor cells. This vector strategy may therefore be of use in the development of immunotherapy for the many carcinomas in which the hMUC-1 antigen is overexpressed.

Cytotoxic effect of replication-competent adenoviral vectors carrying L-plastin promoter regulated E1A and cytosine deaminase genes in cancers of the breast, ovary and colon

Prodrug activating transcription unit gene therapy is one of several promising approaches to cancer gene therapy. Combining that approach with conditionally replication-competent viral vectors that are truly tumor specific has been an important objective of recent work. In this study, we report the construction of a new conditionally replication-competent bicistronic adenoviral vector in which the cytosine deaminase (CD) gene and the E1a gene are driven by the L-plastin tumor-specific promoter (AdLpCDIRESE1a). A similar vector driven by the CMV promoter has also been constructed (AdCMVCDIRESE1a) as a control. We have carried out in vitro cytotoxicity in carcinomas of the breast, ovary and colon, and in vivo efficacy studies with these vectors in an animal model of colon cancer. While the addition of the AdLpCDIRESE1a vector to established cancer cell lines showed significant cytotoxicity in tumor cells derived from carcinomas of the breast (MCF-7), colon (HTB-38) and ovary (Ovcar 5), no significant toxicity was seen in explant cultures of normal human mammary epithelial cells (HMEC) exposed to this vector. The addition of 5-fluorocytosine (5FC) significantly increased the cytotoxicity in an additive fashion of both the AdLpCDIRESE1a and AdCMVCDIRESE1a vectors as well as that of the AdLpCD replication incompetent vector to established tumor cell lines. However, no significant cytotoxicity was observed with the addition of 5FC to explant cultures of normal human mammary epithelial cells that had been exposed to the L-plastin-driven vectors. Studies with mixtures of infected and uninfected tumor cell lines showed that the established cancer cell lines infected with the AdLpCDIRESE1a vector generated significant toxicity to surrounding uninfected cells (the “bystander effect”) even at a ratio of 0.25 of infected cells to infected + uninfected cells in the presence of 5FC. The injection of the AdLpCDIRESE1a vector into subcutaneous deposits of human tumor nodules in the nude mice was potentiated by administering 5-FC by intraperitoneal injection. This treatment resulted in a decreased tumor size and a decreased tumor cell growth rate. The mice treated with a combination of the AdLpCDIRESE1a vector intratumoral injection and intraperitoneal 5FC injections lived much longer than the other experimental groups exposed to the viral vector alone or to the combination of the intratumoral AdLpCD replication incompetent vector injections plus intraperitoneal 5-FC injections. These encouraging results with our newly constructed AdLpCDIRESE1a vector suggest a need for further study of its utility in a preclinical model of intracavitary therapy of pleural or peritoneal carcinomatosis.

Mapping of angiogenic markers for targeting of vectors to tumor vascular endothelial cells

The vasculature of mouse breast tumor spheroids grown on mammary fat pad tissue in an intravital microscopy (IVM) viewing chamber was shown to derive from infiltrating angiogenic mammary vessels. The receptors tissue factor (TF), α V β 3 integrin and Tie-2 were expressed on the vascular endothelium in the periphery but not in the center of the tumor spheroids nor in the mammary tissue nor in smooth muscle tissue, whereas Tie-1 and PCAM-1 were expressed extensively in the entire tumor and in the vascular endothelium of the entire tumor nodule and in normal mammary tissue. TF is a specific target for adenoviral vector-mediated cancer immunotherapy. Subcutaneous injection of the AdfVII/IgG1Fc vector leads to the release into the system circulation of a fVII/IgG1Fc immunoconjugate molecule that binds specifically and tightly to TF on vascular endothelial cells and tumor cells, activating a cytolytic immune response against the targeted cells. We show that a single administration of the AdfVII/IgG1Fc vector destroys the peripheral but not the central vasculature of a tumor spheroid, causing partial tumor regression; additional administrations prevent regeneration of the peripheral vasculature and regrowth of the tumor. These findings indicate that a critical parameter for optimizing tumor damage is the schedule for successive administrations of the AdfVII/IgG1Fc, which should coincide with the regeneration of the peripheral vasculature and continue until the tumor is destroyed.

Vector Targeting Makes 5-Fluorouracil Chemotherapy Less Toxic and More Effective in Animal Models of Epithelial Neoplasms

Purpose: 5-Fluorouracil (5-FU) has been combined in the past with other drugs for the combination chemotherapy for cancers of the breast, ovary, and colon. These drug regimens were limited by the fact that 5-FU fails to kill nondividing cancer cells at the doses that are safe to deliver. The goal of the present study is to test the feasibility of replacing 5-FU in established 5-FU combination chemotherapy with the Ad-LpCDIRESE1A/5-fluorocytosine (5-FC) system for the purpose of reducing toxicity and increasing efficacy. Experimental Design: We have replaced 5-FU in the weekly combination of CPT-11, folinic acid (FA) and 5-FU chemotherapy by 5-FC and an adenoviral vector that carries the L-plastin (Lp) tumor-specific promoter-driven transcription unit encoding the cytosine deaminase gene linked to the E1A gene by an internal ribosomal entry site element. This combination is called “genetic combination therapy.” The goal of using the vector was to decrease the toxicity to normal tissue and to increase the efficacy of therapy in the cancer cells by increasing the concentration of 5-FU sufficiently high that even nondividing cancer cells would be killed by 5-FU through its incorporation into mRNA and consequent inhibition of synthesis of functional proteins. We compared the in vivo efficacy of the genetic combination therapy with the conventional combination chemotherapy in a mouse colon cancer model. Results: Both replication-competent and -noncompetent adenoviral vectors carrying an L-plastin–driven cytosine deaminase transcription unit when combined with 5-FC, CPT-11, and FA showed increased in vitro therapeutic activity that was significantly higher than that of the conventional chemotherapy combination. Tumor-bearing mice treated with the genetic combination therapy showed a statistically significant advantage in terms of increased response rate, response duration, survival, and reduced toxicity when compared with tumor-bearing mice treated with the conventional combination chemotherapy. Conclusions: Replacement of 5-FU in 5-FU–based combination chemotherapy with the Ad-LpCDIRESE1A vector and 5-FU reduces toxicity and increases efficacy. This is a concept that could be potentially applied widely for many forms of cancer treatment.

Vector Prime/Protein Boost Vaccine That Overcomes Defects Acquired during Aging and Cancer

We showed that the Ad-sig-TAA/ecdCD40L vaccine induces a tumor suppressive immune response to the hMUC-1 and rH2N tumor-associated self Ags (TAA) and to the Annexin A1 tumor vascular Ag, even in mice in which anergy exists to these Ags. When the TAA/ecdCD40L protein is given s.c. as a boost following the Ad-sig-TAA/ecdCD40L vector, the levels of the TAA-specific CD8 T cells and Abs increase dramatically over that seen with vector alone, in young (2-mo-old) as well as old (18-mo-old) mice. The Abs induced against hMUC-1 react with human breast cancer. This vaccine also induces a 4-fold decrement of negative regulatory CD4CD25FOXP3-T cells in the tumor tissue of 18-mo-old mice. These results suggest that the Ad-sig-TAA/ecdCD40L vector prime-TAA/ecdCD40L protein boost vaccine platform may be valuable in reducing postsurgery recurrence in a variety of epithelial neoplasms.

Antitumor immune response induced by i.t. injection of vector-activated dendritic cells and chemotherapy suppresses metastatic breast cancer

S.c. injection of the Ad-sig-tumor-associated antigen (TAA)/ecdCD40L vector vaccine has been shown to induce a CD8 immune response against TAA for up to 1 year. The first goal of this article is to test if the injection of autologous dendritic cells infected ex vivo with the Ad-sig-TAA/ecdCD40L can increase the immune response induced against TAA. The second goal is to test the effect of adding local chemotherapy in the form of i.t. injection of the AdCDIRESE1A vector-directed chemotherapy on the immune response induced by i.t. injection of adenoviral vector-activated dendritic cells. The results show that the i.t. injection of the AdCDIRESE1A chemotherapy sensitization vector, which encodes the cytosine deaminase chemotherapy sensitization transcription unit, to the i.t. injection of Ad-sig-ecdCD40L vector-infected dendritic cells increased the level of suppression of the growth of the CCL-51 breast cancer cells. The combination of i.t. injection of the AdCDIRESE1A chemotherapy sensitization vector and Ad-sig-ecdCD40L vector-infected dendritic cells into s.c. CCL-51 breast cancer nodules suppressed the growth of uninjected metastatic tumor nodules in the lung. Finally, adding the i.t. injection of the AdCDIRESE1A chemotherapy sensitization vector to the i.t. administration of dendritic cells infected with a rat HER-2/neu (rH2N)–expressing vector (Ad-sig-rH2N/ecdCD40L) led to the induction of rH2N-specific antitumoral immunity in rH2N transgenic mice (which are anergic to the rH2N antigen). This anti-rH2N immune response suppressed the growth of established H2N-positive NT2 breast cancer more efficiently than did the vector-targeted chemotherapy or Ad-sig-rH2N/ecdCD40L-infected dendritic cell vaccine alone. [Mol Cancer Ther 2006;5(8):1975–85]

Chemotherapy targeted to cancer tissue potentiates antigen-specific immune response induced by vaccine for in vivo antigen loading and activation of dendritic cells.

Our laboratory has created an Ad-sig-TAA/ecdCD40L vaccine platform designed to activate dendritic cells (DCs). Two subcutaneous (s.c.) injections of the TAA/ecdCD40L protein following the s.c. injection of the Ad-sig-TAA/ecdCD40L vector (TAA/ecdCD40L VPP vaccine) further increases the levels of the tumor-associated antigen (TAA)-specific CD8 effector T cells induced by the vector. We tested the combined effect of chemotherapy-induced destruction of tumor cells and TAA/ecdCD40L VPP vaccine which further increases the levels of TAA available to the DCs at the time of vaccination. The chemotherapy was delivered selectively to the tumor cells using intratumoral (i.t.) injection of the AdCDIRESE1A vector followed by intraperitoneal (i.p.) 5-fluorocytosine (5FC). The 5-fluorouracil (5FU) produced in the vector infected the tumor cells, destroys them and releases the TAA for processing and presentation by the DCs. This mode of delivery spares the TAA CD8 effector T cells from the destructive effect of the 5FU when their proliferation is induced by the vaccine. Test mice treated with both the s.c. administered TAA/ecdCD40L VPP vaccine and the AdCDIRESE1A/5FC chemosensitization vector had the smallest tumor volumes and survived longer than mice treated with either of these agents alone (P < 0.001).

Use of Adenoviral Vectors to Target Chemotherapy to Tumor Vascular Endothelial Cells Suppresses Growth of Breast Cancer and Melanoma

To target chemotherapy to tumor vascular endothelial cells (TVECs), we created the AdTie2RprCDFib(knob-RGD+) vector by inserting into an AdEasy adenoviral vector (Ad) backbone: (i) the cytosine deaminase (CD) gene driven by the Tie2 receptor promoter (Tie2Rpr) into the E1 region of Ad; (ii) mutations that reduce binding of the fiber knob to the Coxsackie adenovirus receptor (CAR); and (iii) the RGD peptide into the H1 loop of fiber for binding to the alpha(V)beta(3) integrin receptors on TVECs. To reduce uptake of the AdTie2RprCDFib(knob-RGD+) by reticuloendothelial (RE) and liver cells, we intravenously (i.v.) injected Hetastarch and low-dose Ad (one million vector particles (VPs)) prior to i.v. injection of a therapeutic dose (one billion VPs) of the AdTie2RprCDFib(knob-RGD+) vector. This treatment induced regressions of N202 breast cancer and B16 melanoma without toxicity to normal tissues. We showed that the tumor regression was induced by infection of the TVECs and not by the infection of tumor cells by the AdTie2RprCDFib(knob-RGD+) vector.

TAA/ecdCD40L adenoviral prime-protein boost vaccine for cancer and infectious diseases.

A vaccine platform has been created by attaching the target-associated antigen (TAA) for the vaccine to the extracellular domain (ecd) of the potent immunostimulatory signal CD40 ligand (CD40L). Attachment of the TAA to the CD40L promotes uptake of the TAA into dendritic cells (DCs), binding to Class I as well as Class II MHC leading to presentation of the TAA on the DCs, expansion of the TAA-specific B cell and CD8 effector T-cell lymphocytes, and induction of a memory response. In addition, the TAA/ecdCD40L vaccine can overcome anergy, induce regressions of pre-existing subcutaneous (SC) nodules of cancer cells, and induce high titers of neutralizing antibodies against viral antigens. This vaccine, which can be administered SC as a TAA/ecdCD40L fusion protein, or as expression vectors (viral or plasmid) or as a vector prime-protein boost strategy, is applicable to the development of vaccine for a wide range of cancers and infectious agents.

Targeting of chemotherapy to Tie-2-receptor positive angiogenic endothelial cells of tumor vasculature.

Abstract #902 Background: There are at least three types of cells in tumor tissue which express the Tie2 receptor (Tie2R): dividing vascular endothelial cells (TVECs), Tie2R-expressing monocytes (TEMs) and Tie2R-expressing mesenchymal progenitor cells (TMPCs).
 We tested if the targeting of chemotherapy to these classes of Tie2R positive cells could suppress tumor cell growth.
 Material and Methods: We constructed replication incompetent adenoviral vectors carrying the cytosine deaminase (CD) suicide gene driven by the mouse Tie2R transcriptional promoter and enhancer sequences. In these viruses, we inserted an RGD-4C peptide into the HI loop of the fiber knob domain of the vector to increase its transduction efficiency in TVECs. At the same time, we added two mutations (S408E and P409A) in the AB loop of the fiber, which ablated the CAR-binding ability of the vector. The resulting vector was named AdTie2RCD(MRGD).
 Results: In vitro viral infection assays involving the human umbilical vein endothelial cells (HUVECs) showed that the RGD-modified vectors have a higher transduction efficiency as compared with their adenoviral vector counterparts which have a wild type fiber protein. Mice carrying the rat Her-2-Neu positive N202 mouse breast cancer cells and the mouse B16 melanoma cells were treated with intravenous injections of Hetastarch and the AdTie2RCD(MRGD) vector followed by intraperitoneal injections of 5-Fluorocytosine (5-FC). The Hetastarch was given before the intraveinous infusion of the adenoviral vector in order to reduce the uptake of the adenoviral vector by the reticuloendothelial cell system. The Tie2R targeted chemotherapy sensitization vectors induced greater degrees of suppression of tumor cell growth than did the control group, achieved the similar treatment effect to its CMV promoter counterpart, but with less side effect.
 Histological analysis showed that these vectors specifically targeted the TVECs, TEMs and TMPCs through which they may have exerted cytotoxic effects in the presence of 5-FC on the tumor cells.
 Discussion: Our results showed that N202 breast cancer cell line is more responsive to the Tie2R-targeting therapy compared to B16 mouse melanoma cell line and the Tie2R-directed anti-angiogenic therapy deserves further study, in combination with other types of therapy to pave the way for future clinic trails. Citation Information: Cancer Res 2009;69(2 Suppl):Abstract nr 902.