Human gene marker/therapy clinical protocols

Adenovirus-mediated herpes simplex virus thymidine kinase gene therapy combined with ganciclovir induces hepatoma cell apoptosis

The present study aimed to examine the apoptotic effects of adenovirus (ADV)-mediated herpes simplex virus thymidine kinase (ADV-TK) combined with ganciclovir (GCV) in tissues obtained from patients with hepatocellular carcinoma in order to provide a theoretical basis for the development of this gene therapy program. Apoptosis detection was conducted using the terminal deoxynucleotidyl-transferase-mediated dUTP nick end labelling assay and the apoptosis index was compared between the experimental; and control groups. Furthermore, the protein expression levels of caspase-3, B-cell lymphoma-2 (Bcl-2), Bcl-2-assoicated protein X (Bax) and nuclear factor (NF)-κB were examined in pathological specimens using immunohistochemical staining. The Bax/Bcl-2 ratio and the release of cytochrome c were examined using western blot analysis. Results indicated that combined ADV-TK and GCV treatment significantly increased the number of apoptotic cells compared with the control group (P<0.05). Immunohistological analysis revealed that ADV-TK and GCV treatment significantly increased the number of caspase-3-positive cells, reduced the Bax/Bcl-2 ratio and NF-κB expression levels and promoted the release of cytochrome c compared with the control group (P<0.01). In conclusion, the present results suggest that combined ADV-TK and GCV treatment exerts its effect through the apoptotic signaling pathway.

Targeting the tumor microenvironment to enhance antitumor immune responses

The identification of tumor-specific antigens and the immune responses directed against them has instigated the development of therapies to enhance antitumor immune responses. Most of these cancer immunotherapies are administered systemically rather than directly to tumors. Nonetheless, numerous studies have demonstrated that intratumoral therapy is an attractive approach, both for immunization and immunomodulation purposes. Injection, recruitment and/or activation of antigen-presenting cells in the tumor nest have been extensively studied as strategies to cross-prime immune responses. Moreover, delivery of stimulatory cytokines, blockade of inhibitory cytokines and immune checkpoint blockade have been explored to restore immunological fitness at the tumor site. These tumor-targeted therapies have the potential to induce systemic immunity without the toxicity that is often associated with systemic treatments. We review the most promising intratumoral immunotherapies, how these affect systemic antitumor immunity such that disseminated tumor cells are eliminated, and which approaches have been proven successful in animal models and patients.

The role of herpes simplex virus thymidine kinase in the treatment of solid tumours

Suicide gene therapy is the approach whereby the genetic alteration of a cell renders it susceptible to an otherwise non-toxic prodrug. Suicide gene therapy for solid tumours has progressed rapidly since the concept was originally described: nearly all tumour types have been explored, with some, such as glioma, melanoma and colon cancer frequently used experimentally. The exciting aspect of suicide gene therapy is the bystander effect, the phenomenon whereby there is extended tumour death when only a small fraction is transfected with the suicide gene. This phenomenon implies that there is a reduced need to target specifically all tumour cells, as the effect mechanism itself carries out this function. The bystander effect mode of action has not yet been fully characterised, but the role of gap junctions and the immune system are implicated as the main instruments in its potentiation. This approach is also amenable to pharmacological intervention, which may help to optimise parameters prior to commencing suicide gene therapy. Clinical trails have already commenced using this form of treatment and results are eagerly awaited.

Implications of the network structure of cellular control circuits for the design of anti-cancer vaccine therapies

I describe the use of a statistical mechanical model of a heirarchical network of failure-prone elements as a model for the failure of a network of interconnected biological elements that are or could be involved in the causation of cancer. From its topology, such a model predicts some of the properties of observed oncogene/tumour suppressor gene networks. I show that the same model suggests that a cancer vaccine strategy that targets 'key' network elements, such as p53 or RAS gene products, is not the only effective strategy for a broadly effective anti-cancer therapy. A mixed antigen or whole cell strategy could be as effective as single antigen vaccines, even if the latter are targeted at the most commonly mutated gene products.

Immunotherapy of established tumors in mice by intratumoral injection of an adenovirus vector harboring the human IL-2 cDNA: induction of CD8(+) T-cell immunity and NK activity

Intratumoral (i.t.) injections of an adenovirus encoding the human interleukin-2 (IL-2) under the control of the RSV (Ad-pRSV-IL-2) or CMV (Ad-pCMV-IL-2) promoter were performed in established mastocytoma P815 tumors in B6D2 mice. Both early and long-term survival were found increased in mice treated with Ad-pCMV-IL-2 as compared with those obtained with Ad-pRSV-IL-2: tumor regression was observed in 30--50% of mice for the former and 5--15% for the latter. Difference in efficacy between the two vectors was directly correlated to the amount of IL-2 produced i.t. between 24 and 48 hours postinjection, which reached 10--20 ng/tumor for Ad-pCMV-IL-2 and 0.3--0.5 ng/tumor for Ad-pRSV-IL-2. In both cases, expression in the tumor was clearly detectable for a period of 7--10 days postinjection. Serum IL-2 was not detectable in mice treated with Ad-pRSV-IL-2, whereas expression peaked at a total of 1--2 ng at 24 hours but declined very rapidly in the Ad-pCMV-IL-2-treated group. Constant production of IL-2 inside the tumor was necessary for successful therapy because i.t. injections of recombinant IL-2 at levels up to 1 microg for five consecutive days did not lead to antitumoral activity. Evidence of induced systemic immunity following Ad-pCMV-IL-2 injections was obtained from rechallenge experiments in which tumor-free mice after treatment rejected a subsequent contralateral injection of a lethal dose of P815 tumor cells and from the observation that regression of nontreated tumors occurred in animals bearing bilateral tumors that were treated i.t. in a single tumor with Ad-pCMV-IL-2. P815-specific cytotoxic T lymphocytes (CTL) were found specifically in spleen cells from cured mice or rechallenged mice but not in control mice. Interestingly, limiting dilution analysis of anti-P815 CTL precursor (CTLp) frequency revealed a significant increase in mice cured of their tumor as compared to that obtained in naive mice or control mice treated or not with Ad-IL-2 but whose tumor was growing. In vivo depletion of T-cell subsets, as well as natural killer cells at the time of i.t. injections with Ad-pCMV-IL-2, demonstrated that both CD8(+) T cells and natural killer cells, but not CD4(+) T cells, were required for successful therapy. Finally, mice preimmunized with Ad-null viruses were severely compromised in their capacity to eradicate established P815 tumors after Ad-pCMV-IL-2 therapy, at least when neutralizing antibody titers reached a critical level.

Efficacy of repeated adenoviral suicide gene therapy in a localized murine tumor model

BACKGROUND

Gene therapy using adenovirus to deliver herpes simplex virus thymidine kinase (Ad.HSVtk) followed by the administration of the prodrug ganciclovir has been an effective anticancer therapy in models of localized tumor (including malignant mesothelioma) and is currently being evaluated in clinical trials. To optimize this approach, we studied the effects of repeated injections of Ad.HSVtk in an animal model of localized tumor in both naive and immunized mice.

METHODS

Immunocompetent animals with established abdominal tumor were treated with either one or three (given weekly) intraperitoneal injections of Ad.HSVtk (10(9) plaque-forming units) followed by daily ganciclovir and monitored for survival. Survival studies were also performed in mice previously immunized with adenovirus.

RESULTS

Animals treated with multiple courses of Ad.HSVtk showed significantly improved survival versus singly injected animals and control animals with some long-term survivors in the multiple injected group. Preexisting neutralizing immunity did not diminish this survival advantage.

CONCLUSIONS

Multiple treatments using an adenoviral vector to deliver HSVtk significantly improves survival in a murine intraperitoneal tumor model. The presence of preexisting neutralizing antibodies does not blunt this effect. Repeat Ad.HSVtk is a feasible approach and may be a useful strategy in human cancer gene therapy.

Genetic immunotherapy for cancer

Genetic immunization refers to treatment strategies where gene transfer methods are used to generate immune responses against cancer. Our growing knowledge of the mechanisms regulating the initiation and maintenance of cytotoxic immune responses has provided the rationale for the design of several genetic immunization strategies. Tumor cells have been gene-modified to express immune stimulatory genes and are then administered as tumor vaccines, in an attempt to overcome tumor cell ignorance by the immune system. With the description of well-characterized tumor antigens, multiple strategies have been proposed mainly aimed at optimal tumor antigen presentation by antigen-presenting cells (APC). Among APC, the dendritic cells have been recognized as the most powerful cells in this class, and have become the target for introducing tumor antigen genes to initiate antitumor immune responses. The detailed knowledge of how the immune system can be activated to specifically recognize tumor antigens, and the mechanisms involved in the control of this immune response, provide the basis for modern genetic immunization strategies for cancer treatment.

Prospects for vaccination in prostate cancer

Prostate cancer continues to be a major cause of morbidity and mortality. Surgical and medical management of the disease has improved but there is little effect upon overall survival. Novel therapies such as immunotherapy offer the potential of treating the disease by stimulating the immune system to mount a response to the cancer systemically. This review highlights the pitfalls and progress in the understanding of the role of the immune system in malignancy and also explains the theory behind prostate cancer vaccine trials.

Gene Therapy 2000

This article reviews 1) the use of gene transfer methods to genetically manipulate hematopoietic stem cell targets, 2) recent advances in technology that are addressing problems that have prevented widespread successful translation of gene transfer approaches for the cure of disease, and 3) recent regulatory issues related to human gene therapy trials.

In Section I, Dr. Nienhuis describes the use of alternative viral envelopes and vector systems to improve efficiency of transduction of hematopoietic stem cells. Major limitations of stem cell transduction are related to low levels of viral receptors on the stem cells of large animal species and the low frequency of cycling stem cells in the bone marrow. Attempts to circumvent these limitations by exploiting non-oncoretroviral vectors and pseudotyping of Moloney vectors with alternative envelopes are discussed.

In Section II, Dr. Hawley addresses new strategies to improve the expression of transgenes in cells derived from long-term reconstituting hematopoietic stem cells. Transgene silencing in transduced hematopoietic stem cells remains an obstacle to gene therapy for some gene sequences. New generations of retroviral backbones designed to both improve expression and reduce silencing in primary cells are explored.

In Section III, Drs. Smith and Cornetta update regulatory issues related to human gene therapy trials. Increased scrutiny of human trials has led to changes in requirements and shifts in emphasis of existing regulations, which apply to human gene therapy trials. The current Food and Drug Administration's structure and regulations and the roles of the Recombinant DNA Advisory Committee of the NIH and other sponsors and partners in gene therapy trials are reviewed.

Gene Therapy 2000

This article reviews 1) the use of gene transfer methods to genetically manipulate hematopoietic stem cell targets, 2) recent advances in technology that are addressing problems that have prevented widespread successful translation of gene transfer approaches for the cure of disease, and 3) recent regulatory issues related to human gene therapy trials.

In Section I, Dr. Nienhuis describes the use of alternative viral envelopes and vector systems to improve efficiency of transduction of hematopoietic stem cells. Major limitations of stem cell transduction are related to low levels of viral receptors on the stem cells of large animal species and the low frequency of cycling stem cells in the bone marrow. Attempts to circumvent these limitations by exploiting non-oncoretroviral vectors and pseudotyping of Moloney vectors with alternative envelopes are discussed.

In Section II, Dr. Hawley addresses new strategies to improve the expression of transgenes in cells derived from long-term reconstituting hematopoietic stem cells. Transgene silencing in transduced hematopoietic stem cells remains an obstacle to gene therapy for some gene sequences. New generations of retroviral backbones designed to both improve expression and reduce silencing in primary cells are explored.

In Section III, Drs. Smith and Cornetta update regulatory issues related to human gene therapy trials. Increased scrutiny of human trials has led to changes in requirements and shifts in emphasis of existing regulations, which apply to human gene therapy trials. The current Food and Drug Administration's structure and regulations and the roles of the Recombinant DNA Advisory Committee of the NIH and other sponsors and partners in gene therapy trials are reviewed.

Costimulation of transduced T lymphocytes via T cell receptor-CD3 complex and CD28 leads to increased transcription of integrated retrovirus

Primary human T lymphocytes were transduced at high efficiency with the Moloney murine leukemia virus (Mo-MuLV) vector, LNC-mB7-1, in which an internal cytomegalovirus (CMV) promoter drives expression of the murine B7-1 cDNA. Compared with transduced T cells expanded in IL-2 or reactivated with soluble antibodies to CD3 or CD28, transgene expression was significantly increased after activation on immobilized anti-CD3 antibodies (CD3i) or by simultaneous activation on immobilized anti-CD3 and anti-CD28 antibodies (CD3i/CD28i). A similar pattern of transgene expression was observed in T cells transduced with Mo-MuLV LNC-EGFP. Proviral copy number was maintained in LNC-mB7-1-transduced T cells expanded in IL-2 or reactivated on CD3i/CD28i. Substantial increases in LNC-mB7-1 steady state mRNA in reactivated T lymphocytes, compared with those maintained in IL-2, correlated with increased transcription of the LNC-mB7-1 proviral DNA. Furthermore, T cells transduced with the Mo-MuLV ZIPPGK-mADA, in which the mADA cDNA is driven by an internal human phosphoglycerate kinase (PGK) promoter, showed increases in steady state ZIPPGK-mADA RNA on reactivation. High levels of transgene expression were evident irrespective of cell cycle position in both CD4+ and CD8+ lymphocytes. After reactivation, increases in LNC-mB7-1 mRNA were observed in the presence of the protein synthesis inhibitor cycloheximide, indicating that proteins involved in upregulating transgene expression preexisted in transduced lymphocytes. Induction of transgene expression on CD3i/CD28i showed a dose-dependent decrease in transgene expression when incubated with selective protein kinase inhibitors. These data provide new insights into the mechanisms governing transgene expression driven by Mo-MuLV constructs containing internal promoters in transduced primary T lymphocytes.

Molecular evaluation of biopsy and autopsy specimens from patients receiving in vivo retroviral gene therapy

We used the polymerase chain reaction (PCR) to assay for the presence of retroviral vector and replication-competent retrovirus (RCR) in autopsy and biopsy specimens from patients who received inoculations of retroviral vector producer cells (VPCs) into brain tumors or apparently normal tissues surrounding resected tumors. The PCR assays were capable of detecting 1 or more proviral copies of vector or RCR in 500,000 cells. Of 113 patients treated in clinical trials between 1994 and 1997, autopsy specimens were available from 32 patients. Brain tumor biopsies were also available from 24 patients. A total of 346 specimens was analyzed. Vector DNA was detected in 55% of tumor samples and 22% of brain samples obtained from resection margins. In contrast, most of the nonbrain tissues were negative for vector DNA; only low levels (<0.03%) of vector sequence were detected in 6 of 240 (2.5%) nonbrain tissues. Vector DNA was not detected in gonadal tissues from 12 men and 10 women. More importantly, RCR was not detected in any of the 134 biopsy and autopsy tissues tested, including all brain tumor, brain, and gonadal specimens. These results comprise the largest data set on molecular analysis of autopsy specimens from patients receiving retroviral gene therapy and indicate that distribution of retroviral vectors following injection of high doses of VPCs is limited to the site of inoculation.

Is there a future for gene therapy?

The requirements for successful gene therapy are stated and brief details are given of the gene therapy trials in humans which have been approved by the NIH during the years 1989-1997. An indication is given of the gene therapy trials that have been carried out in animal models of Duchenne muscular dystrophy with emphasis on the Golden Retriever dog model. Problems facing somatic gene therapy for inherited muscle diseases are predominantly the following: the extent of the spread of expression from the injection site, the duration of expression and the need for systemic delivery. Brief details of the problems are given and possible ways of overcoming the difficulties are outlined. These include the use of multiple intramuscular injections, increasing the permeability of the extracellular matrix of muscle, inducing mitosis in myoblasts, the use of ex vivo gene transfer, using modified viruses as vectors or synthesized transporter molecules, the use of mechanisms which combat the action of killer T cells, upregulation of isoforms or of alternative proteins such as utrophin for dystrophin and the use of genetic correction methods such as the use of antisense oligonucleotides. It is concluded that there is a potential future for somatic gene therapy in the inherited muscle diseases.

Adenovector-mediated gene delivery of interleukin-2 in metastatic breast cancer and melanoma: results of a phase 1 clinical trial

We conducted a phase 1 trial of direct injection of an E1, E3-deleted adenovirus encoding interleukin-2 (AdCAIL-2) into subcutaneous deposits of melanoma or breast cancer. Twenty-three patients were injected at seven dose levels (10(7)-10(10) p.f.u). Local inflammation was observed at the site of injection in 60% of patients, but side-effects were otherwise minor. Incomplete local tumor regression occurred at the site of injection in 24% of patients, but no conventional clinical responses were seen. Circulating CD4 and CD8 counts fell significantly 24 h after injection. Post-injection biopsies demonstrated tumor necrosis and lymphocytic infiltration with the predominant tumor-infiltrating cells both CD3- and CD8-positive. Vector-derived sequences were detected in 14 of 18 biopsies examined 7 days after injection and vector-derived hIL-2 mRNA was detected in 80% of 7-day biopsies processed after injection of 10(8) p.f.u. of AdCAIL-2 or higher. While IL-2 was detectable by ELISA in tumor biopsies at 48 h, no protein was detectable in injected tumors after 7 days and no circulating IL-2 was detectable at any time-point. No Ad5E1 sequences were detected either before or after injection indicating absence of replication-competent virus or endogenous E1-like sequence; furthermore, only rare vector shedding was detected. Anti-adenovirus and neutralizing antibody titers were elevated 1 month after injection in all patients. This trial therefore confirms the safety of use of adenoviral vectors for gene delivery in humans and demonstrates successful transgene expression even in the face of pre-existing immunity to adenovirus.

Gene and cell transfer for specific immunotherapy

The realisation that human tumor cells may express and process tumor specific and tumor associated antigens has increased interest in immunotherapeutic approaches to cancer treatment. This interest has been coupled with a burgeoning ability to genetically modify tumor cells and components of the immune system, in an effort to maximize the anti-neoplastic response. In a number of settings, gene modified tumor vaccines, cytotoxic T cells and dendritic cells are producing both immunomodulation and clinically evident benefits. Continued exploration of this approach seems well justified.