Structural features of the combining site region of Erythrina corallodendron lectin: role of tryptophan 135

The last two decades have led to a greater understanding of the genetic basis of human malignancy. Although numerous genetic alterations have been detected in cancer, activation of oncogenes and inactivation of cell cycle regulators (e.g., tumor suppressor genes) are now known to play a critical role in the progression of the disease. Therapeutic strategies based on specific molecular alterations in cancer include reintroduction of wild-type tumor suppressor function to cells lacking the gene. p53 gene therapy provides an attractive strategy to test the potential clinical feasibility of this approach. Alterations in p53 function are present in approximately half of all malignancies, and expression of wild-type p53 can result in apoptosis in human tumor cells. This review summarizes current investigations with p53 gene therapy, highlighting the preclinical efforts with adenoviral, retroviral, and lipid-based gene delivery systems. A comprehensive review of the various clinical targets suggested for p53 gene therapy is presented together with challenges and prospects for future clinical investigation.     

Temporary internal fixation of the scaphotrapezio-trapezoidal joint for the treatment of Kienb?ck''s disease: a preliminary study

Gene transfer into a panel of non-small cell lung cancer (NSCLC) cells by adenoviral (Ad) and retroviral (RV) vectors was studied. Indexed to multiplicity of infection (MOI), Ad vectors transduce squamous, adenosquamous, and malignant mesothelioma cells with greater efficiency than large cells or adenocarcinoma cells. Transduction-sensitive cells bind the Ad vector with specificity for the Ad fiber knob, and internalize vector efficiently. Transduction-refractory cells bind and internalize vector by less efficient pathways. Like Ad vectors, there is heterogeneity in RV transduction efficiencies of different NSCLC subtypes. With respect to the most common cell type metastatic to the pleural space (adenocarcinoma), amphotropic retroviral vectors transduce cells of this subtype more efficiently (at a lower MOI) than Ad. RV transduction is not solely dependent on cellular replication, and both permissive and refractory cell lines express the mRNA for the amphotropic RV receptor. These observations suggest that neither Ad nor RV vectors will suffice a priori as the optimal gene transfer vehicle, and successful gene therapy of lung cancer may require tumor-specific or patient-specific vectors.     

Gene transfer: a review of methods and applications

Gene transfer is a potentially powerful tool for the treatment of a wide variety of diseases. The transfer of these genes is achieved by utilizing a variety of vectors, including retroviral, adenoviral, adeno-associated virus (AAV) and a number of non-viral mechanisms. Numerous studies have successfully demonstrated transduction of genes into target cells with a variety of vectors, and have provided 'proof-in-principle' that gene transfer can result in prolonged in vivo expression of transduced genes, albeit at low quantities. Furthermore, gene marking studies in acute myeloblastic leukemia (AML), chronic myeloid leukemia (CML) and neuroblastoma have elegantly demonstrated that gene-marked tumor cells contribute to relapse following autologous transplantation. However none of the studies examining the therapeutic benefit of gene therapy has definitively demonstrated a clinically meaningful benefit. Nonetheless, the results of studies involving gene transfer for severe combined immunodeficiency (SCID), chronic granulomatous disease (CGD), melanoma and lung cancer highlight the potential benefit of this strategy. This review will discuss mechanisms of achieving gene transfer into target cells. It will examine some of the pre-clinical and clinical results to date and will discuss some of the potential uses of gene transfer for therapeutic purposes.     

Stable in vivo gene transduction via a novel adenoviral/retroviral chimeric vector

Gene therapy to correct defective genes requires efficient gene delivery and long-term gene expression. The available vector systems have not allowed the simultaneous achievement of both goals. We have developed a chimeric viral vector system that incorporates favorable aspects of both adenoviral and retroviral vectors. Adenoviral vectors induce target cells to function as transient retroviral producer cells in vivo. The progeny retroviral vector particles are then able to stably transduce neighboring cells. In this system, the nonintegrative adenoviral vector is rendered functionally integrative via the intermediate generation of a retroviral producer cell. The chimeric vectors may allow realization of the requisite goals for specific gene-therapy applications.     

Gene therapy for colon cancer

The enormous number of newly diagnosed cases of colorectal cancer that occur each year and the lack of agents that are highly effective for all patients underscore the need for novel approaches to combating the disease. Gene therapy as a developing treatment modality is already well established, with a number of trials ongoing and a vast range of other approaches being assessed in animal and cell culture experiments. In this brief review, we have discussed five gene therapy trials in colon carcinoma that are ongoing or in the approval process in the United States. The gene therapy approaches being employed can be divided into three major categories: (1) enzyme/prodrug systems (HSVtk/ganciclovir; CD/5-fluorocytosine); (2) tumor suppressor gene replacement therapy with wild-type p53; and (3) immune-gene therapy which is based on cytokine or tumor antigen expression to induce tumor immunity (e.g., CEA). Replication-deficient recombinant adenoviral vectors are predominantly used for colon cancer gene therapy, because they can be produced at high titer and they readily infect a number of different cell types. One trial uses polynucleotide therapy for antitumor immunization with intramuscular injection. All of these studies are phase I trials, principally designed to evaluate safety, but they will also provide data on gene delivery. Some trials may provide some insight into potential therapeutic effects. We have alluded to some of the concerns on toxicity related to the use of adenovirus, risks and side effects from transgenes, lack of tumor-specificity of transgene expression, and potential problems with efficient gene delivery to solid tumors. The clinical trials, however, will provide insight that will inform design of future studies with respect to dose, form, and frequency of administration, as well as to the value of biologic and clinical endpoints. The molecular analysis of the fundamental basis of colon cancer has moved at a remarkable pace and that progress seems set to continue. Thus, the basic foundations for gene therapy are undoubtedly in place: a clinical need; growing understanding of basic tumor biology; and ever-improving delivery systems. The field is at a very early stage in its evolution, and one concern is that the considerable hurdles that must be overcome are seen as examples of the failure of cancer gene therapy; however, we believe these challenges will be overcome. The authors also believe that colon cancer gene therapy is likely to take new directions, such as use as adjuvant to radical surgery, rather than attempts to treat end-stage disease when the liver is replaced by metastases. Other new directions might include prophylactic gene-based immunization against a panel of well-characterized tumor antigens, at least for persons shown to be at high risk of colon cancer because of genetic or other predisposition. A marriage between gene therapy approaches and conventional anticancer treatments such as radiotherapy and chemotherapy also seems likely. There is already evidence of this move with demonstration of synergism between p53 replacement and radiotherapy and chemotherapy. It is also likely that therapies will be developed that combine elements from the cancer gene therapies discussed previously, namely, suicide gene transfer, immune modulation, and modulation of defective cancer genes. Perhaps one of the main concerns is not that researchers in cancer gene therapy want to walk before they can run, but that the public and government agencies believe they can. The next 10 years will be an interesting time in the development of novel treatments against colon cancer.     

Rapid adenoviral transduction of freshly resected tumour explants with therapeutically useful genes provides a rationale for genetic immunotherapy for colorectal cancer

To develop protocols for the molecular immunotherapy of colorectal cancer, we compared the efficacy of three separate classes of therapeutic genes to induce antitumour responses in a murine colorectal cell model. Thus, the effects of two cytokines (IL-2 and GM-CSF) were compared with those of a costimulatory gene (B7.1) and a suicide gene (HSVtk). The rank order of efficacy against primary tumour growth was HSVtk[GCV], B7.1 > puro, IL-2 > GM-CSF, neo whereas the order of efficacy in inducing antitumour immunity was GM-CSF, IL-2, > B7.1, HSVtk[GCV] > puro, neo in a prophylactic vaccination model. To exploit these data in a clinically relevant and realistic way, we also demonstrated that colorectal tumours can reproducibly be explanted and established in short-term culture. Finally, a rapid transduction protocol has been developed by which, using adenoviral vectors, as many as 90% of the cells in these fresh tumour explants can be engineered to express high levels of the clinically relevant genes (GM-CSF or IL-2) within 1-2 weeks of surgery. Adenovirus-mediated gene delivery was reproducibly and significantly more efficient than retroviral transduction using the MFG-beta-Gal retroviral vector over the time-frame of importance for vaccination. Hence, combination of the animal model data with the ex vivo modification protocol suggests that vaccination of colorectal patients of the appropriate stage will be possible and effective.     

Gene therapy of neoplastic meningosis

Gene therapy of neoplastic meningosis is a promising new approach that relies on introduction of 'suicide' genes into cancer cells. The most commonly used gene has been the herpes virus thymidine kinase gene (HSV-tk) which has been delivered to cancer cells via retroviral or adenoviral vectors. A bystander cytocidal effect to non-transduced tumor cells has been documented and is dependent upon intercellular communication via gap junctions. A variety of gene therapy approaches using the HSV-tk system have been used in experimental models of neoplastic meningosis with promising results. Optimizing vector design and bystander cytotoxicity is a prerequisite for successful gene therapy in patients with neoplastic meningosis.     

Molecular surgery for human colorectal cancer with tumor suppressor p53 gene transfer

Recent advances in molecular biology have demonstrated that multistep genetic alterations are involved in the carcinogenesis of human colorectal cancer and that alteration of the p53 gene by mutation, deletion, or rearrangement is a major factor in this process. Human gene therapy has become a reality with the development of effective techniques for delivering the gene to the target cells. The efficacy of gene therapy for various types of genetic disease now being evaluated in clinical trials. These findings led us to develop a novel gene therapeutic strategy for human colorectal cancer that could replace the abnormal p53 gene using a recombinant, replication-defective adenoviral vector (termed Adp53). Infection with Adp53 induced rapid apoptotic cell death in DLD-1 and LoVo human colorectal cancer cell lines differing in their p53 status. Treatment with cisplatin following infection with Adp53 significantly suppressed the growth of WiDr colorectal cancer cells compared to single treatments alone. Thus restoration of wild-type p53 function exhibited an antitumor effect by inducing apoptosis as well as by markedly enhancing the effect of common chemotherapeutic agents in human colorectal cancer cells. In addition, Adp53 infection was antiangiogenic in SW620 human colorectal cancer cells. The application of this technology to human cancer therapy is now in progress. The article reviews recent highlights in this rapidly evolving field.     

Gene therapy: a primer for radiologists

Gene therapy is one of the most rapidly evolving areas in medicine. Radiologists should have an understanding of basic techniques used to identify and clone a gene and insert it into a vector capable of directing expression in mammalian tissues. DNA delivery systems include retroviral vectors (RNA viruses), adenoviral vectors (DNA viruses), and cationic liposomes, along with strategies that involve ultrasound-directed gene transfer, computed tomography-guided gene transfer, and transcatheter gene delivery, in particular via the hepatic artery. Genes being evaluated in preclinical and clinical trials include oncogenes, antioncogenes (tumor suppressor genes), suicide genes, conventional antimetabolites, antiangiogenesis factors, secreted immunostimulatory cytokines such as interleukins and interferons, and immunomodulatory cell surface proteins, including foreign HLA proteins and costimulatory molecules. A foundation in molecular biology is needed for the practicing radiologist interested in but unfamiliar with current gene therapy terminology and experimental strategies. Such a foundation will encourage the dissemination of basic biologic, diagnostic imaging, and interventional oncoradiologic developments and should facilitate integration of the radiologist into the gene therapy team.     

Gene therapy for primary and metastatic pancreatic cancer with intraperitoneal retroviral vector bearing the wild-type p53 gene

BACKGROUND: Metastatic pancreatic cancer is uniformly fatal because no effective chemotherapy is available. Mutations in the p53 tumor suppressor gene are found in up to 70% of pancreatic adenocarcinomas. We examined the efficacy of a retroviral vector containing the wild-type p53 gene on metastatic pancreatic cancer in a nude mouse model. METHODS: Bxpc3 human pancreatic cancer cells were transduced with either a retroviral p53 vector or an LXSN empty vector. Cells were examined for incorporation of tritiated thymidine to determine the effect of p53 retroviral transduction on DNA synthesis, and a TACS2 assay for apoptosis was performed. The functional activity of p53 in transduced cells was assessed by Western blot analysis with an antibody to WAF1/p21. In vivo effects of intraperitoneal injections of the p53 vector were examined in a nude mouse model of peritoneal carcinomatosis. RESULTS: Cells treated with the p53 vector exhibited a 59% to 85.5% reduction in cell number compared with the control cells (P < .05). p53-treated cells demonstrated decreased incorporation of tritiated thymidine (12.7% +/- 0.7% vs 17.5% +/- 1.4%; P = .002), increased staining for apoptosis, and increased expression of the WAF1/p21 protein. Treatment of nude mice with the retroviral p53 vector resulted in a significant inhibition of growth of the primary pancreatic tumor, as well as the peritoneal tumor deposits, compared with the LXSN control vector. CONCLUSIONS: Intraperitoneal delivery of a retroviral p53 vector may provide a novel treatment approach for peritoneal carcinomatosis from pancreatic cancer.     

Muscle maturation: implications for gene therapy

Skeletal muscle is a promising target tissue for gene therapy, for both muscle and non-muscle disorders. A variety of methods have been studied to transfer genes into skeletal muscle, including retroviral, adenoviral and herpes simplex viral vectors. However, various factors impede muscle-based viral gene therapy. Here, we discuss why some viral vectors cannot efficiently transduce mature muscle fibers, and describe some new approaches to overcome this barrier.     

Construction of new retroviral producer cells from adenoviral and retroviral vectors

A combination of adenoviral and retroviral vectors was used to construct second generation packaging cells that deliver marker genes to target cells. A vector based upon Moloney murine leukemia virus (MoMLV) was used to deliver marker genes, and an adenovirus-based delivery system was used to deliver MoMLV structural genes (gag pol and env) to cultured cells. The procedure transformed the cells into new retroviral producer cells, which generate replication-incompetent retroviral particles in the culture supernatant for transferring marker genes to target cells. The titer of the retroviral-containing supernatant generated from the second generation producer cells reached above 10(5) c.f.u./ml, which is comparable to the MoMLV-based producer cell lines currently used in human gene therapy trials. These observations suggest that this new gene transfer scheme is technically feasible. The vector and procedures may be adapted for experimental human gene therapy in which the new producer cells are transplanted into patients for continuous gene transfer.     

High-resolution magnetic resonance imaging: three-dimensional trabecular bone architecture and biomechanical properties

The development of vectors that are capable of efficient gene delivery is crucial to the success of gene therapy. We have developed both recombinant viral and nonviral vectors with the goal of correcting genetic abnormalities in cancer cells that are responsible for malignant transformation. Infection of cancer cells by recombinant adenovirus (Adv) indicates that the level of transduction is variable and dependent on the virus-to-cell ratio. Infection of cells with Adv/p53 resulted in levels of tumor suppressor p53 gene expression that could mediate tumor cell growth suppression and apoptosis, both in vitro and in vivo. The treatment of cancer cells with cisplatin prior to Adv transduction resulted in a higher level of therapeutic gene expression. Epidermal growth factor (EGF)/DNA complexes targeted to cancer cells overexpressing the EGF receptor resulted in efficient transduction of several lung cancer cell lines in vitro. As a result, these vectors provide improved methods with which to treat cancer in the clinical setting with gene therapy.     

Genetic basis of neurological tumours

Neurological tumours are common neoplasms of both adults and children. Recent studies have begun to delineate the genetic abnormalities that underlie such tumours, and have implicated two classes of genes, oncogenes and tumour suppressor genes. Most investigations have focused on those astrocytomas that affect the cerebral hemispheres of adults, since these are the most common and malignant brain tumours. The high-grade astrocytomas that affect adults, such as glioblastoma multiforme, often have amplification of the epidermal growth factor receptor (EGFR) oncogene and loss of a variety of chromosomal loci that probably harbour tumour suppressor genes. Of the various tumour suppressor gene loci, the p53 gene on chromosome 17p has been studied most closely and has been shown to be mutated in both low- and high-grade astrocytomas. These genetic alterations may provide a means for subdividing astrocytomas into diagnostic categories. For instance, p53 gene mutations occur more commonly in glioblastomas from young adults and women, while EGFR gene amplification is more common in glioblastomas from older adults and men. For the other primary CNS tumours, genetic studies remain in their infancy. The neurocutaneous syndromes, such as neurofibromatosis types 1 and 2, have provided unique insights into neurological oncogenesis. The NF1 gene on chromosomes 17q and its product, neurofibromin, may be important in the formation of neurofibrosarcomas, while the NF2 gene on chromosome 22q and its product, merlin, are probably involved in the formation of schwannomas and other nervous system tumours. The further characterization of these and other neurological tumour genes will undoubtedly illuminate many other areas in neurooncology.     

Loss of heterozygosity of BRCA1, TP53 and TCRD markers analysed in sporadic endometrial cancer

Genetic alterations of tumour suppressor genes, for which loss of heterozygosity (LOH) is one mechanism of gene inactivation, are important steps in the development of endometrial cancer. To investigate the clinical relevance of LOH of BRCA1 (17q21), TP53 (17p13) and TCRD (14q11) in endometrial cancer, polymerase chain reaction (PCR)-based fluorescent DNA technology for the detection of microsatellite polymorphisms was applied. One hundred and thirteen archival endometrial cancer samples with matched normal tissues were examined. Allele loss at three loci were correlated with age, tumour size, lymph node status, metastases, stage, histological types, grade, expression of oestrogen receptor (ER) and progesterone receptor (PgR), family history of cancer, previous history of cancer or precursor lesions, and previous history of hormone replacement therapy (HRT). LOH for BRCA1 was detected in 18.1%, of TP53 in 26.9%, and of TCRD in 26.3% of informative cases. LOH of BRCA1 correlated with medium grade, positive ER status, and family history of cancer; LOH of TP53 correlated with younger age, high grade, positive PgR status, and with tumours from patients without HRT; LOH of TCRD correlated only with family history of cancer. LOH at all three loci correlated only with grade and positive family history. Allele loss of one of the three tumour suppressor loci did not correlate with disease-free survival (DFS), but LOH of BRCA1 correlated significantly with decreased overall survival (OS). The latter, together with the correlation of LOH of BRCA1 locus with steroid hormone receptor expression, might give a hint to the potential involvement of the co-localised 17 beta-hydroxysteroid dehydrogenase (HSD) gene in the development of endometrial cancer.     

IL-1/IL-3 gene therapy of non-small cell lung cancer (NSCLC) in rats using 'cracked' adenoproducer cells

Cytokine gene therapy was studied in established L42 tumours in syngeneic rats. L42 is a transplantable non-immunogenic non-small cell lung cancer (NSCLC). Genes coding for human interleukin-1 alpha and for rat interleukin-3 beta were transferred by injecting producer cells of recombinant adenovirus vectors into the tumour in attempts to achieve high concentrations of the cytokines inside the tumor without systemic toxicity. Limited tumour growth delay was obtained with viable producer cells. For logistic reasons stocks of pooled frozen producer cells allowed intensive treatment of groups of tumour bearing rats. The cells were lysed by thawing before administration. Ten daily injections of such 'cracked' producer cells induced reproducible tumour responses. These were due to local release of cytokines, not to systemic effects. Growth retardation also occurred in contralateral tumours which were not injected. When rats carrying established tumours were vaccinated with lysates of tumours collected during treatment with 'cracked' producer cells, significant tumour growth retardation was obtained. We speculate that both cytokines, if produced at sufficiently high concentrations in tumours, induce inflammation which in turn initiates an immune response against tumours growing at a distant site. These findings seem to justify further exploration of IL-1 and IL-3 gene transfer for the treatment of cancers.     

Clinical implication of screening p53 gene mutations in head and neck squamous cell carcinomas

The role of the tumour-suppressor gene p53 in the tumorigenesis of head and neck cancer has been well established, but the clinical significance of p53 alteration is still unclear. A group of 50 patients with head and neck squamous cell carcinoma (HNSCC) were investigated for p53 alterations. DNA was extracted from fresh tumour samples and polymerase chain reaction/single-strand conformation polymorphism analysis was used to detect p53 gene mutations in the region from exon 5 to exon 9. In addition, p53 protein overexpression was assessed by immunohistochemistry using the monoclonal antibody DO-7 on paraffin-embedded tissue sections. p53 gene mutations were found in 45% and p53 protein expression was detected in 61.2% of tumour samples. While p53 protein expression was not correlated with any clinical factors, p53 gene mutations indicated local regional recurrences of HNSCC. The risk of locoregional recurrence was significantly greater in patients with a p53 gene mutation than in patients with the wild-type p53 gene (P = 0.001). Multivariate analysis confirmed p53 gene mutation to be an independently predictive factor for the tumour recurrence (P = 0.0064). When we analysed p53 gene mutation in 12 patients with primary and recurrent tumours, we found that 4 patients (33.3%) had a different p53 gene mutation in the recurrent tumour from that in the original primary tumour. The results indicate that p53 gene mutations and not protein overexpression are valuable predictors for tumour recurrences and for differential diagnosis of a second primary HNSCC.     

Two Li-Fraumeni syndrome families with novel germline p53 mutations: loss of the wild-type p53 allele in only 50% of tumours

We describe two Li-Fraumeni syndrome families. Family A was remarkable for two early childhood cases of adrenocortical tumours, family B for a high incidence of many characteristic cancers, including a childhood case of choroid plexus tumour. Using direct sequencing, we analysed exons 5-9 of the p53 gene in constitutional DNA of individuals from both families and found two novel germline mutations in exon 5. In family A, we detected a point substitution in codon 138 (GCC to CCC), which resulted in the replacement of the alanine by a proline residue. Family B harboured a single-base pair deletion in codon 178 (CAC to -AC), resulting in a frameshift and premature chain termination. Three out of six tumours examined from both families, a renal cell carcinoma, a rhabdomyosarcoma and a breast cancer, showed loss of heterozygosity and contained only the mutant p53 allele. The remaining three neoplasms, both adrenocortical tumours and the choroid plexus tumour retained heterozygosity. Immunohistochemistry with anti-p53 antibody confirmed accumulation of p53 protein in tumours with loss of heterozygosity, while the remaining tumours were p53 negative. These results support the view that complete loss of activity of the wild-type p53 need not be the initial event in the formation of all tumours in Li-Fraumeni individuals.     

Identification of proteins that interact with a protein of interest: applications of the yeast two-hybrid system

Colorectal cancer remains a major health problem. Few therapies are effective apart from surgery, and survival has increased little in recent years. This is despite the fact that screening by colonoscopy can potentially remove nearly all colorectal tumours before they become malignant. Molecular genetics has identified some inherited mutations (such as at APC and the mismatch repair loci) that predispose to colon cancer and some somatic mutations (such as at APC and p53) that cause sporadic colon tumours. We review the likely role of these and other genes in colorectal tumorigenesis. We also highlight areas of relative ignorance in colon cancer and emphasise that many important genes, especially those that cause invasion and metastasis, remain to be identified. Colorectal cancer is, however, a well characterised tumour, as regards both its natural history and its histopathology; there are consequently good prospects for advances in colon cancer genetics, with probable benefits for its treatment. We anticipate: (a) that new genes predisposing to colon tumours, including those conferring relatively minor risks, will be characterised; (b) genes and proteins important in invasion and metastasis will be identified; (c) the network of protein interactions in which molecules such as APC are involved will be elucidated; (d) large-scale studies of somatic mutations in tumours will provide accurate predictions of prognosis and suggest optimal therapeutic regimens; and (e) new potential targets for therapy will be identified. Whilst molecular genetics is by no means sufficient for progress in preventing and treating colon cancer, it is a necessary and central part of such advances.