Immunogenicity and efficacy of intradermal tattoo immunization with adenoviral vector vaccines.

Since intradermal delivery of DNA vaccines via tattoo device is an efficient strategy to induce antigen-specific immune responses, we evaluated this route of application for adenoviral vector vaccines in mice. Although expression levels were comparable after i.d. injection and i.d. tattoo immunization of adenoviral vectors, the tattoo application confined antigen expression to the upper layers of the dermis. Both delivery approaches resulted in strong CD8+ T-cell and humoral immune responses to three different antigens and conferred protection against mucosal challenge with respiratory syncytial virus. However, in contrast to results obtained with DNA vaccines, intradermal tattoo immunization did not provide any obvious advantage in comparison to simple intradermal injection of the adenoviral vector vaccines.

Comparison of herpes simplex virus- and conditionally replicative adenovirus-based vectors for glioblastoma treatment.

In this study we compared side-by-side the anti-neoplastic activity of the oncolytic herpes simplex virus-1 (HSV-1) vector G47Delta with that of a conditionally replicative adenoviral vector for the treatment of glioblastoma. We analyzed the transduction efficiency of permanent glioblastoma cell lines and short-term cultures of glioblastoma cells with HSV.Luc and four adenovirus type 5 (Ad5)-based vectors that differed only in their fiber gene (Ad5.Luc, AdlucRGD, and the fiber chimeric vectors Ad5/3.Luc and Ad5/35.Luc). In the tested short-term cultures of glioblastoma cells the vectors Ad5/35.Luc and HSV.Luc had an equal transduction efficiency which was approximately 70% higher than that of Ad5.Luc. In a subcutaneous xenograft glioblastoma model in nude mice we observed a significantly higher local tumor control with the G47Delta vector compared to the conditionally replicative Ad5/35 adenovirus. We confirmed in glioblastoma that the intratumoral expression of measles virus fusogenic membrane glycoproteins (FMG) encoded by replication-defective Ad5/35 or HSV-1 amplicon vectors synergistically enhances chemotherapy with temozolomide. The anti-neoplastic effect was superior when the replication-defective FMG encoding vectors were trans-complemented for replication with the respective oncolytic vector. This approach was necessary due to packaging constraints of adenovirus. At day 100, of 6 treated animals 1 was alive that received the Ad5/35- and 3 that received the HSV-1-based triple therapy. In an intracranial glioblastoma xenograft model we demonstrated the applicability of this strategy. Due to the higher oncolytic efficacy and packaging capacity of the HSV-1 vectors compared to adenovirus, these vectors are promising for the treatment of glioblastoma.

Synergy between expression of fusogenic membrane proteins, chemotherapy and facultative virotherapy in colorectal cancer.

Using Chou-Talalay median effect analysis, we demonstrated in permanent and short-term cultures of colorectal cancer cells that the expression of measles virus fusogenic membrane glycoproteins (FMGs) in combination with chemotherapy often causes over most of the cytotoxic dose range synergistic cell killing. In this combined treatment, we observed strongly enhanced annexin V binding and caspase-3/7 activity when compared to single-agent treatment. Furthermore, we showed increased expression of heat-shock protein (Hsp)70 and Hsp90alpha, but not of Hsp60. In a subcutaneous HT-29 colorectal xenograft model, we demonstrated that the administration of a replication-defective adenoviral or herpes simplex virus (HSV) amplicon vector (Ad.H/F or HSV.H/F) encoding tumor-restricted FMG in combination with FOLFOX significantly enhanced treatment outcome when compared to treatment with each compound individually. To increase the fraction of tumor cells expressing the FMG, we trans-complemented the Ad.H/F and HSV.H/F vector with the respective oncolytic replication-restricted adenovirus Ad.COXDeltaMK or HSV-1 G47Delta vector. At the end of the observation period (day 100), eight out of 10 animals that received G47Delta, HSV.H/F and FOLFOX were alive and tumor free. Administration of the analogous adenovirus-based regimen resulted in four out of 10 long-term survivors. We demonstrated that the expression of FMG in combination with chemotherapy can significantly enhance treatment outcome, which is further enhanced by combination with trans-complementing oncolytic vectors.

In vitro pharmacodynamic evaluation of antiviral medicinal plants using a vector-based assay technique.

AIMS: Medicinal plants are increasingly being projected as suitable alternative sources of antiviral agents. The development of a suitable in vitro pharmacodynamic screening technique could contribute to rapid identification of potential bioactive plants and also to the standardization and/or pharmacokinetic-pharmacodynamic profiling of the bioactive components. METHODS AND RESULTS: Recombinant viral vectors (lentiviral, retroviral and adenoviral) transferring the firefly luciferase gene were constructed and the inhibition of viral vector infectivity by various concentrations of plant extracts was evaluated in HeLa or Hep2 cells by measuring the changes in luciferase activity. Cytotoxicity of the extracts was evaluated in parallel on HeLa or Hep2 cells stably expressing luciferase. Amongst the 15 extracts screened, only the methanol (ME) and the ethyl acetate (ET) fractions of the lichen, Ramalina farinacea specifically reduced lentiviral and adenoviral infectivity in a dose-dependent manner. Further, chromatographic fractionation of ET into four fractions (ET1-ET4) revealed only ET4 to be selectively antiviral with an IC50 in the 20 microg ml(-1) range. Preliminary mechanistic studies based on the addition of the extracts at different time points in the viral infection cycle (kinetic studies) revealed that the inhibitory activity was highest if extract and vectors were preincubated prior to infection, suggesting that early steps in the lentiviral or adenoviral replication cycle could be the major target of ET4. Inhibition of wild-type HIV-1 was also observed at a 10-fold lower concentration of the extract. CONCLUSIONS: The vector-based assay is a suitable in vitro pharmacodynamic evaluation technique for antiviral medicinal plants. The technique has successfully demonstrated the presence of antiviral principles in R. farinacea. SIGNIFICANCE AND IMPACT OF STUDY: Potential anti-HIV medicinal plants could rapidly be evaluated with the reported vector-based technique. The lichen, R. farinacea could represent a lead source of antiviral substances and is thus worthy of further studies.

AV.TK-mediated killing of subcutaneous tumors in situ results in effective immunization against established secondary intracranial tumor deposits.

Gene transfer vectors expressing herpes simplex thymidine kinase (HSVtk), in addition to direct killing of tumor cells, often have an associated local "bystander effect" mediated by metabolic coupling of tumor cells. A systemic antitumor effect mediated by the immune system, termed the distant bystander effect, has also been reported. We have observed the development of cytotoxic T-lymphocyte (CTL) populations and long-lasting antitumor immunity following treatment of subcutaneous tumors with an adenoviral vector expressing HSVtk (AV.TK) and ganciclovir (GCV) in rat glioma model. This vaccination effect seen with AV.TK/GCV treatment of subcutaneous tumor could even abrogate or retard growth of previously established secondary intracranial tumors.

Oncolytic viruses as therapeutic agents.

The concept of using viruses as oncolytic agents has a long history. However, relatively new developments are the use of these viruses as gene delivery vehicles and the restriction of viral replication and lysis to tumour cells. The latter is attempted by the use of tumour-specific promoters, which transcriptionally target viral genes involved in replication, or by deletion of viral functions dispensable for replication in tumour cells but essential for productive infection of normal cells. In addition, retargeting of the viral tropism towards tumours by capsid modifications has been examined. Although much progress has been made in developing oncolytic vectors for clinical use, there is still a long way to go to determine which combinations of virus, gene therapy, surgery, radiation, and/or chemotherapy will provide improved therapy for the control and eradication of a variety of human cancers. First controlled clinical trials with an oncolytic adenovirus in combination with chemotherapy have shown encouraging antineoplastic activity. For future vector developments it will be crucial to achieve maximum vector distribution and transgene expression within tumours, to trigger a specific systemic immune effector response against treated and untreated lesions, and to modulate the immune system to avoid immune-mediated inactivation or destruction of the virus. In the context of replication-competent vectors, suicide genes might be used as fail-safe mechanism in the case of a runaway infection.

Expansion of hepatic and hematopoietic stem cells utilizing mouse embryonic liver explants.

Ex vivo embryonic liver explant culture is a novel and attractive approach to obtain abundant hepatic and hematopoietic stem cells. Gene therapy of autologous hepatic and hematopoietic stem cells represents an alternative therapeutic approach to liver transplantation for genetic and metabolic disorders. In this study we characterize the growth and differentiation of hepatic stem cells utilizing embryonic liver cultures. Day 9.5 liver buds are microdissected and cultured under specific conditions. Modulation of growth conditions by addition of hepatocyte growth factor, Flt-3 ligand, and stem cell factor leads to enrichment of hepatic progenitor cells in embryonic liver explants. Under these conditions, we also demonstrate the role of a novel marker PRAJA-1 to identify hepatic stem cells and transitional hepatocytes. Utilization of dexamethasone enhanced pseudolobule formation with increased hepatocytic and biliary differentiation. Transforming growth factor-beta leads to enrichment of biliary cells in the culture. Gut formation is enhanced in the presence of interleukin-3 and blood formation by increasing the mesodermal tissue in these cultures. We also show increased retroviral-mediated expression of the green fluorescent protein expression in the expanded hepatic and hematopoietic stem cells under different culture conditions. Thus, the embryonic liver explant culture is an attractive source for hepatic progenitors and is a possible step towards generating nontumorigenic immortalized hepatocytes with possible transplantation applications.

Gene transfer of heat-shock protein 70 reduces infarct size in vivo after ischemia/reperfusion in the rabbit heart.

BACKGROUND: Heat-shock protein 70 (HSP 70) plays a role in myocardial protection. No studies are available, however, to show that direct gene transfer of HSP 70 reduces myocardial infarction in vivo. METHODS AND RESULTS: Rabbit hearts were injected with vehicle or Ad.HSP70 at 3 sites (1.5x10(9) pfu, 50 microL/site) in the left ventricle (LV). Four days later, hearts were removed, and expression of inducible (HSP 70) and constitutive (HSC 70) proteins was measured in the LV and right ventricle (RV). Subsets of 5 to 7 animals in the vehicle-, Ad.lacZ-, and Ad.HSP70-treated groups were subjected to 30 minutes of ischemia and 3 hours of reperfusion. Infarct size was measured by tetrazolium staining. Increased expression of HSP 70 was observed in LV injected with Ad.HSP70 compared with vehicle-treated hearts. HSP 70 was undetectable in RV, the noninjected region of the heart. The expression of HSC 70 remained unchanged in hearts treated with vehicle or Ad.HSP70. Infarct size (% risk area) decreased to 24.5+/-2.8 in Ad.HSP70-injected hearts compared with 41.9+/-2.8 and 42.7+/-2.5 in the vehicle- and Ad.LacZ-treated hearts (P<0.01). The infarct size was not different between the vehicle- and Ad.LacZ-treated hearts (P>0.05). The risk areas (% of LV) were not different among the 3 groups, ie, 50.1+/-5.2, 47.7+/-3.5, and 53.3+/-2.9 in vehicle-, Ad.lacZ-, and Ad.HSP70-treated groups (P>0.05). CONCLUSIONS: Direct gene delivery of HSP 70 in vivo reduces the severity of ischemic injury in the heart.

Therapy of peritoneal carcinomatosis from colon cancer with oncolytic adenoviruses.

BACKGROUND: The major emphasis on the safety of viral vectors for gene delivery has led to the generally accepted approach of disabling their ability to replicate and thus their potential capacity to spread throughout a tumor by consecutive rounds of infection and lysing neighboring cells. METHODS: In this study we evaluated three herpes simplex virus-1 thymidine kinase (HSV-tk) carrying replication-competent adenoviral vectors with and without the Ad5 E1B 55-kDa gene, wild-type adenovirus type 5 (Ad5wt), and a prototypical replication-deficient adenovirus expressing HSV-tk (Ad.TK) for their cytoreductive effects in a peritoneal carcinomatosis model from human HT-29 colon cancer cells in nude mice. RESULTS: The survival of nude mice treated with the replication-defective adenoviral vector Ad.TK was enhanced when followed by GCV. In contrast, administration of GCV diminished the anti-tumor efficacy of the replication-competent HSV-tk expressing vectors. However, the intrinsic oncolytic effect of all replication-competent viruses was superior to that of Ad.TK+GCV. Furthermore, the oncolysis of the E1B 55-kDa-positive viruses was significantly greater than that of the E1B 55-kDa-deleted vector. CONCLUSIONS: The more efficient diffusion of viral particles in the peritoneal cavity, when compared to the microenvironment of solid tumors and the virostatic effects of GCV, most likely antagonized the anticipated enhanced cytotoxicity of the replication-competent vectors from the use of its gene directed enzyme prodrug system. Nevertheless, in a clinical setting, the HSV-tk/GCV system allows efficient termination of viral replication in the case of a runaway infection. The results of this study warrant further evaluation of controllable viral replication as a treatment modality for cancer, especially in combination with conventional therapies (e.g. chemotherapy).

The role of the E1B 55 kDa gene product in oncolytic adenoviral vectors expressing herpes simplex virus-tk: assessment of antitumor efficacy and toxicity.

In this study, we evaluated three herpes simplex virus-1 thymidine kinase (HSV-tk) carrying replication-competent adenoviral vectors with and without the Ad5 E1B 55 kDa gene to assess whether this gene product has an influence on their antitumor efficacy, replication kinetics, and potential hepatotoxicity. Furthermore, we assessed the efficacy of these vectors in combination with ganciclovir (GCV). When compared with wild-type adenovirus, the recombinant vectors, in particular the E1B 55 kDa-deleted vector Ad.TK(RC)(II), generated a more efficiently cytopathic effect in proliferating cells, independently of their p53 phenotype. In a s.c. A549 lung cancer xenograft model, the cytoreductive effect of Ad.TK(RC)(II) was enhanced when followed by GCV treatment. In contrast, the efficacy of both E1B 55 kDa-positive vectors could not be further improved by GCV. In an i.p. MDAH 2774 ovarian cancer xenograft tumor model, the survival of animals treated with a prototypical replication-deficient adenovirus expressing HSV-tk (Ad.TK) was improved compared to controls when followed by GCV. In contrast, the cytoreductive efficacy of the replication-competent vectors was diminished when combined with the virostatic GCV. However, the antitumor effect of all replication-competent vectors was superior to combination chemotherapy with paclitaxel and carboplatin. In both tumor models, the oncolytic effect of the E1B 55 kDa-positive vectors was greater than that of Ad.TK(RC)(II). In an attempt to assess the toxicity of these vectors in a nonpermissive host, the viruses were administered systemically to immunocompetent and immunodeficient mice. Greater hepatotoxicity was seen with i.v. administration of the replication-competent viruses than with Ad.TK and in immunocompetent hosts, suggesting involvement of the immune system in the induction of tissue damage. The E1B 55 kDa gene had no significant influence on the liver toxicity of the vectors in this system. At therapeutic doses, intratumoral or i.p. injection of all vectors was well tolerated. Importantly, these replication-competent HSV-tk-expressing vectors were highly susceptible to GCV, representing an effective fail-safe mechanism to abolish viral replication in a clinical setting. Controllable intratumoral viral replication holds promise as a new treatment modality for cancer.

Therapy of head and neck squamous cell carcinoma with an oncolytic adenovirus expressing HSV-tk.

Currently available therapeutic modalities for advanced head and neck squamous cell carcinoma (HNSCC), such as radical surgery, high-dose radiotherapy, and chemotherapy, are of limited efficacy. Overall survival has not significantly improved over the past 30 years; thus, HNSCC represents a promising target for new therapeutic approaches, such as gene therapy. A major obstacle to the development of effective suicide gene therapy strategies that rely on in situ transduction of tumor cells is the poor distribution of the vector throughout the tumor. To address this problem we evaluated the use of Ad.OW34, an Elb 55 kD and HSV-tk-carrying, replication-competent adenoviral vector that has a wild-type adenovirus phenotype in replicating cells, in combination with ganciclovir (GCV) as a treatment for HNSCC xenografts in nude mice and compared its efficacy with that of a standard replication-deficient adenovirus expressing HSV-tk (Ad.TK). In this model, Ad.OW34 had a significantly greater antitumor effect than the traditional Ad.TK vector, administered alone or in combination with GCV. Interestingly, GCV did not further enhance the oncolytic efficacy of Ad.OW34. GCV also aborts viral replication and thus represents a fail-safe feature of this vector not found in wild-type adenovirus.

Synergy between the herpes simplex virus tk/ganciclovir prodrug suicide system and the topoisomerase I inhibitor topotecan.

An established principle of antineoplastic chemotherapy is that multidrug regimens are generally superior to single-agent therapy. This prompted us to elucidate whether the topoisomerase inhibitor topotecan (TPT) could enhance the efficacy of the herpes simplex virus thymidine kinase gene/ganciclovir (HSV-tk/GCV) system for the treatment of cancer. We assessed the interaction between these two treatments in murine MC38 and human HT-29 colon carcinoma cell lines that were genetically modified to constitutively express HSV-tk, sensitizing them to GCV. Synergistic cell killing was observed in a clonogenic assay over most of the cytotoxic dose range by the median-effect principle of Chou and Talalay (Adv. Enzyme Regul. 1984; 22:27-55). Subcutaneous tumor models, using the same cell lines in C57BL/6 and athymic nude mice, respectively, demonstrated that the combination of GCV and TPT resulted in statistically significant enhanced survival relative to single-agent treatment. In addition, nude mice bearing HT-29 tumor xenografts were treated with an Ad5 E1b Mr 55,000 attenuated replication-competent adenovirus expressing HSV-tk (Ad.TK(RC)) either alone or in combination with GCV and/or TPT. These experiments demonstrated that Ad.TK(RC) followed by GCV and TPT was more efficacious than any other treatment tested. Our results suggest that for antineoplastic therapy, molecular chemotherapy based on the HSV-tk/GCV system combined with traditional chemotherapy is a logical and practical future direction to pursue. Suicide gene therapy is the approach whereby genetically altering a cell makes it susceptible to an otherwise relatively nontoxic prodrug. By this approach it is possible to achieve relatively high concentrations of the toxic metabolites in the transduced cells while maintaining low systemic levels of the active drug. The most often used metabolic suicide gene transfer system is the HSV-tk/GCV paradigm, which is currently being used in cancer therapy or as a safety modality. The low response rate observed in the early clinical HSV-tk cancer trials may be due to failure in achieving adequate transduction efficiency and/or prodrug concentration within the tumor. The combination of such suicide gene prodrug systems with adjunctive drugs resulting in synergistic cytotoxicity might improve the clinical utility of this approach.

Enzyme prodrug gene therapy: synergistic use of the herpes simplex virus-cellular thymidine kinase/ganciclovir system and thymidylate synthase inhibitors for the treatment of colon cancer.

The goal of this study was to improve the therapeutic index of the herpes simplex virus-thymidine kinase/ganciclovir (HSV-tk/GCV) system by the addition of thymidylate synthase (TS) inhibitors. For this, we assessed the potential of GCV to synergistically interact with 5-fluorouracil (5-FU), ZD1694 (Tomudex), and (E)-5-(2-bromovinyl)-2'-deoxyuridine in HSV-tk-expressing murine MC38 STK and human HT-29 STK colon carcinoma cell lines. Synergistic cell killing was observed in a clonogenic assay over most of the cytotoxic dose range by the median-effect principle of Chou and Talalay (T. C. Chou and P. Talalay, Adv. Enzyme Regul., 22: 27-55, 1984). In a s.c. HT-29 STK xenograft tumor model, we demonstrated that the combination of GCV and 5-FU resulted in statistically significant enhanced animal survival over single-agent treatment. Furthermore, we showed that the combination of GCV and ZD1694 in association with the HSV-tk/GCV system was at least as effective as GCV/5-FU in vitro and in vivo. The mechanism for the observed synergy is most likely attributable to the increased GCV phosphorylation in the presence of the tested TS inhibitors. Our data suggest that the HSV-tk/GCV metabolic suicide gene transfer system could serve as an adjuvant of the presently used TS inhibitors, thus potentially improving the efficacy of present cancer gene therapy approaches.

Adenoviral vectors capable of replication improve the efficacy of HSVtk/GCV suicide gene therapy of cancer.

A major obstacle to the success of gene therapy strategies that directly target cancer cells is the poor vector distribution within solid tumors. To address this problem, we developed an E1b 55 kDa attenuated, replication-competent adenovirus (Ad.TKRC) which expresses the herpes simplex-1 thymidine kinase (HSVtk) gene to sensitize tumors to ganciclovir (GCV). Efficacy of this combined strategy was tested in nude mice with subcutaneous human A375 melanoma and ME180 cervical carcinomas. Intratumoral injection of a replication-defective adenoviral vector expressing HSVtk (Ad.TK) followed by GCV treatment resulted in doubling of the survival time of mice bearing A375 tumors and 20% long-term survival of mice with ME180 tumors. Treatment of tumors with Ad.TKRC without GCV resulted in a similar antitumor effect, confirming that the replicating vector has an oncolytic effect. When GCV was initiated 3 days after Ad.TKRC injection, survival of mice with each tumor type was greatly prolonged, with 60% of animals with ME180 tumors surviving for over 160 days. These results confirm that both the oncolysis caused by a replicating virus and suicide/prodrug gene therapy with HSVtk/GCV have potent antitumor effects. When combined, these two approaches are complementary resulting in a significantly improved treatment outcome.

Therapy of colon cancer with oncolytic adenovirus is enhanced by the addition of herpes simplex virus-thymidine kinase.

A major obstacle to the successful application of suicide gene therapy strategies that rely on in situ transduction of tumor cells is the poor distribution of the vector throughout the tumor mass. To address this problem, we evaluated the use of Ad.TK(RC), an E1b Mr 55,000 deleted replicating adenoviral vector engineered to express the herpes simplex virus type 1 thymidine kinase gene (HSV-tk) in combination with ganciclovir (GCV) as a treatment for human colon cancer xenografts in nude mice. We compared the efficacy of this system with that of a standard replication-deficient adenovirus expressing HSV-tk (Ad.TK) in mice bearing LS180 tumors. In this system, Ad.TK(RC) alone was as effective as a traditional Ad.TK vector in combination with GCV. The addition of GCV significantly enhanced the antitumor effect of Ad.TK(RC). Furthermore, we demonstrated that the survival of HT-29 human colon cancer xenografted mice treated with Ad.TK(RC) and GCV was prolonged compared with Ad.TK(RC) alone or with administration of a single cycle of topotecan. These data demonstrate that the addition of direct viral oncolysis to the HSV-tk/GCV suicide gene system resulted in a striking improvement in treatment efficacy and that it may offer advantages over the use of chemotherapeutic agents for treatment of localized disease.

In situ use of suicide genes for therapy of brain tumours.

Suicide gene therapy represents a new therapeutic approach to the treatment of patients with otherwise incurable malignant brain tumours. This strategy involves the introduction of a gene that renders the tumour cell susceptible to an otherwise nontoxic prodrug. The most often used genetic prodrug activation system is the herpes simplex virus thymidine kinase/ganciclovir (HSV-tk/GCV) paradigm. An important aspect of this system is the 'bystander effect', the extension of cytotoxic effects to untransduced cells. For gene delivery, retroviral, adenoviral vectors and HSV-1 mutants have been used. Clinical studies have revealed that the HSV-tk/GCV approach is safe, but also that responses are observed only in very small brain tumours, indicating insufficient vector distribution and very low transduction efficiency with replication-deficient vector systems. To improve treatment efficacy, the use of replication-competent oncolytic vectors in combination with new or improved prodrug-suicide gene systems as a part of a multimodal approach is warranted. In the context of replication-competent vectors, suicide genes might also be used as fail-safe genes in the case of runaway infection.

Generation of a conditionally neo(r)-containing retroviral producer cell line: effects of neo(r) on retroviral titer and transgene expression.

We have developed a method for generating high-titer retroviral producer cell lines conditionally containing a neomycin resistance gene (neo(r)) based on the Cre/loxP system. For this, a bicistronic retroviral splicing vector carrying the green fluorescence protein (GFP) and a marker gene cassette consisting of internal ribosome entry site (IRES) and neo(r) flanked by loxP sites, was constructed and conveniently used to generate a G418 resistant vector producer cell line. Following titer determination and verification of the biological activity of the retroviral supernatants, the selectable expression cassette which was no longer required was excised from the provirus by transient Cre expression using an adenoviral vector. This strategy led to precise excision of neo(r) and generation of retroviral supernatants containing functional 'neo-less' retroviral particles without detrimental effects on the high vector titers found in the parental neo(r)-containing producer lines. GFP expression was significantly increased after the excision of neo(r), in both the producer lines and retrovirally transduced target cells. Reintroduction of neo(r) did not alter GFP expression, suggesting that the neo(r) gene and/or its gene product per se are not acting as a transcriptional silencer.

Efficient directional cloning of recombinant adenovirus vectors using DNA-protein complex.

We describe an efficient cloning system utilizing adenoviral DNA-protein complexes which allows the directional cloning of genes into adenoviral expression vectors in a single step. DNA-protein complexes derived from a recombinant adenovirus (AVC2.null) were isolated by sequential use of CsCl step gradients followed by isopycnic centrifugation in a mixture of CsCl and guanidine HCl. AVC2.null is an adenoviral expression vector containing unique restriction sites between the human CMV-IE promoter and the SV40 intron/polyadenylation site. Transgenes were prepared for cloning into this vector by introduction of compatible restriction sites by PCR. A vector expressing rat granulocyte-macrophage colony-stimulating factor (GM-CSF) was constructed using DNA-protein complex as well as by traditional recombination techniques. The efficacy of our adenoviral cloning system utilizing DNA-protein complex was two logs higher than that seen using homologous recombination. All viruses generated by directional ligation of the insert into the vector DNA-protein complexes contained the desired transgene in the correct orientation. This technique greatly simplifies and accelerates the generation of recombinant adenoviral vectors.