Generation of an adenovirus vector lacking E1, e2a, E3, and all of E4 except open reading frame 3

Generation and characterization of E1/E2a/E3/E4-deficient adenoviral vectors encoding human factor VIII

The use of adenoviral vectors for gene therapy has been limited due to host immune responses directed toward the vector and/or transgene and vector toxicity. To decrease adenoviral vector immunogenicity and toxicity, we attenuated viral gene expression by eliminating E1, E2a, E3, and E4 early genes from the adenoviral backbone. Two highly attenuated, fourth-generation (Av4) E1/E2a/E3/E4-deficient adenoviral vectors encoding human factor VIII (FVIII) under the control of a liver-specific albumin promoter were generated. One Av4 vector (Av4DeltaE4FVIII) was deficient in the entire E4 coding region and the second vector contained a deletion of the E4 region, except for open reading frame 3 (orf 3; Av4orf3FVIII). The Av4 vectors were compared to an E1/E2a/E3-deficient third-generation vector (Av3H8101) containing an analogous transgene expression cassette in vitro and in vivo following intravenous administration in hemophiliac mice. In vitro transduction of Hep3B cells revealed at all three vectors expressed functional FVIII. However, the Av4DeltaE4FVIII vector could not be scaled-up for in vivo studies. Both Av3H8101 and Av4orf3FVIII initially expressed similar levels of FVIII in hemophiliac mice. However, at 3 months, animals treated with the Av4orf3FVIII vector no longer expressed FVIII while Av3H8101-treated mice displayed persistent FVIII expression. Liver enzyme analyses of plasma samples revealed that the Av4orf3FVIII vector was significantly less hepatotoxic than the Av3H8101 vector. These data demonstrate that further attenuation of the adenoviral vector backbone by removal of the majority of the E4 coding region significantly diminished vector toxicity; however, the duration of transgene expression was reduced.

Viral vectors for gene therapy: the art of turning infectious agents into vehicles of therapeutics

Considered by some to be among the simpler forms of life, viruses represent highly evolved natural vectors for the transfer of foreign genetic information into cells. This attribute has led to extensive attempts to engineer recombinant viral vectors for the delivery of therapeutic genes into diseased tissues. While substantial progress has been made, and some clinical successes are over the horizon, further vector refinement and/or development is required before gene therapy will become standard care for any individual disorder.

Production of first generation adenovirus vectors: a review

In the past decade, adenovirus vectors have generated tremendous interest, especially in gene therapy applications. In the so-called 'first generation' adenovirus vectors, the transgenes are inserted in place of the E1 region, or less often the E3 region. Although second-generation and helper-dependent adenovirus vectors will probably prevail in the future in applications that require long-term gene expression, first generation adenovirus vectors will remain very useful in other settings, such as cancer and vaccination, or simply to transfect cell lines that are refractory to other transfection methods. Until a few years ago, the construction of first generation adenovirus vectors was a labor-intensive and time-consuming process. More than 20 methods have appeared that facilitate their construction and are reviewed below.

Gene therapy and molecular approaches to the treatment of hereditary muscular disorders

Gene therapy for inherited muscle disease is an active area of research and development. Initial emphasis has been on gene replacement but alternative approaches are increasingly being considered in order to overcome difficulties, such as the immune rejection of transduced cells, the need for appropriate and tissue-specific control of expression, and the requirement for systemic spread in some conditions. However, the most significant obstacles to the clinical success of gene therapy are still the lack of efficiency and accuracy of gene medicine delivery.

In vivo dose threshold effect of adenovirus-mediated factor VIII gene therapy in hemophiliac mice

While much is known about adenovirus biology from its development as a therapeutic gene delivery vehicle, an important question remains regarding the appropriate in vivo vector dose. We describe here an in vivo dose threshold effect with an adenoviral vector expressing human Factor VIII (FVIII) in hemophiliac mice. Upon administration of vector doses between 6 x 10(10) and 2 x 10(10) vector particles per mouse, FVIII was expressed linearly, whereas a dose of 1 x 10(10) vector particles per mouse did not result in detectable levels of FVIII activity. In contrast, in vitro transduction studies demonstrated linear transgene expression over 2 to 3 log units. To further define this dose threshold effect, a vector-mixing study was performed. Mice were injected with a total vector dose of 6 x 10(10) particles containing admixtures of FVIII vector plus a control vector lacking a transgene (null vector). With the admixture, FVIII activity was detected in mice that received 1 3 1010 particles of the FVIII vector, indicating that maintenance of the total viral input at 6 x 10(10) particles per mouse circumvented the threshold dose effect. This threshold dose effect could not be attributed to dose-dependent differences in liver toxicity nor to dose-dependent induction of cellular and humoral immune responses. Southern blot analysis of livers revealed that mice receiving the vector admixture contained FVIII DNA, accounting for the observed FVIII expression, whereas mice receiving 1 x 10(10) particles of FVIII vector had barely detectable FVIII DNA. These results suggest that the threshold effect is an in vivo phenomenon that will have important implications in defining the therapeutic window of adenoviral vectors for clinical applications.

Potential applications of gene therapy in the patient with cancer

The elderly population has much to gain from the advances of molecular medicine, although at present genetic pharmacology remains mostly at the conceptual level. Cancer, in particular, is an increasing health burden and the majority (over 70%) of gene therapy trials are aimed at tackling this problem. Available strategies employ both viral and synthetic vectors with the selective delivery and expression of therapeutic genes a pivotal requirement. Clinical trials are now in progress with a view to modulating disease at many different levels, including the direct replacement of abnormal genes. suicide-gene formulations, and the delivery of 'gain of function' genes, which seek to alter the malignant phenotype by indirect means, such as, immunopotentiation and stromal reorganisation. Early data from these studies is tantalising and we must remain optimistic that gene therapy will benefit the patient with cancer by both reducing morbidity and extending life.

The E4-6/7 protein functionally compensates for the loss of E1A expression in adenovirus infection

The E1A gene products are required and sufficient for activation of adenovirus gene expression in cultured cells. The E4-6/7 gene product induces the binding of the cellular transcription factor E2F to the viral E2a promoter region. The induction of E2F binding to the E2a promoter in vitro is directly correlated with transcriptional activation of the E2a promoter in vivo. The E2 region encodes the viral replication proteins, yet adenoviruses lacking E4-6/7 function demonstrate no defective phenotype in infected cells. Here we show that the E4-6/7 protein can functionally compensate for E1A expression in virus infection. In the absence of the E1A gene products, expression of the E4-6/7 protein is sufficient to displace retinoblastoma protein family members from E2Fs, activate expression of early region 2 via induction of E2F DNA binding to the E2a promoter region, and significantly enhance replication of an E1A-defective adenovirus. These results have implications in the regulation of viral gene expression and for the development of recombinant adenovirus vectors.

Multiply deleted [E1, polymerase-, and pTP-] adenovirus vector persists despite deletion of the preterminal protein

BACKGROUND

The inherent limitations of [E1-]Ad vectors as gene therapy vehicles suggest that further modifications may improve their overall performance profiles. However, Ad vector modifications can have untoward effects on their basic biology, e.g., some helper-virus dependent Ad vectors have been found to be unstable without the presence of preterminal protein (pTP) activities. Despite this concern, we generated a new class of helper-virus independent Ad vector that was multiply deleted for the E1, polymerase, and pTP genes, and investigated the ramifications of these deletions upon several vector performance parameters.

METHODS

The construction and propagation of an [E1-, polymerase-, pTP-]Ad vector was achieved with the use of trans-complementing cells co-expressing the Ad E1, polymerase and pTP genes.

RESULTS

High titer production of the [E1-, polymerase-, pTP-]Ad vector was successfully accomplished via conventional Ad purification techniques. This unique class of Ad vector was capable of long-term gene transfer in vivo (despite lacking pTP functions) that was concomitant with a significantly decreased hepatic toxicity.

CONCLUSIONS

Previous studies had suggested that Ad genome persistence in vivo may be dependent upon the presence of low level vector genome replication and/or pTP functions. Our results suggest that [E1-, polymerase-, pTP-]Ad vectors can overcome these barriers. The further benefits afforded by the use of this class of Ad vector (increased cloning capacity, high level growth, decreased propensity to generate replication competent Ad (RCA), decreased toxicity) suggests that they will be highly beneficial for use in several aspects of human gene therapy.

Latest developments in gene transfer technology: achievements, perspectives, and controversies over therapeutic applications

Over the last decade, more than 300 phase I and phase II gene-based clinical trials have been conducted worldwide for the treatment of cancer and monogenic disorders. Lately, these trials have been extended to the treatment of AIDS and, to a lesser extent, cardiovascular diseases. There are 27 currently active gene therapy protocols for the treatment of HIV-1 infection in the USA. Preclinical studies are currently in progress to evaluate the possibility of increasing the number of gene therapy clinical trials for cardiopathies, and of beginning new gene therapy programs for neurologic illnesses, autoimmuno diseases, allergies, regeneration of tissues, and to implement procedures of allogeneic tissues or cell transplantation. In addition, gene transfer technology has allowed for the development of innovative vaccine design, known as genetic immunization. This technique has already been applied in the AIDS vaccine programs in the USA. These programs aim to confer protective immunity against HIV-1 transmission to individuals who are at risk of infection. Research programs have also been considered to develop therapeutic vaccines for patients with AIDS and generate either preventive or therapeutic vaccines against malaria, tuberculosis, hepatitis A, B and C viruses, influenza virus, La Crosse virus, and Ebola virus. The potential therapeutic applications of gene transfer technology are enormous. However, the effectiveness of gene therapy programs is still questioned. Furthermore, there is growing concern over the matter of safety of gene delivery and controversy has arisen over the proposal to begin in utero gene therapy clinical trials for the treatment of inherited genetic disorders. From this standpoint, despite the latest significant achievements reported in vector design, it is not possible to predict to what extent gene therapeutic interventions will be effective in patients, and in what time frame.

Optimization of the helper-dependent adenovirus system for production and potency in vivo

Helper-dependent (HD) adenoviral vectors devoid of all viral coding sequences provide for safe and highly efficient gene transfer with long-lasting transgene expression. High titer stocks of HD vectors can be generated by using the cre-recombinase system. However, we have encountered difficulties with this system, including rearranged HD vectors and variable efficiency of HD vector rescue. These problems represent a major hindrance, particularly with regard to large-scale production. To overcome these limitations, we have modified the system in two ways: We constructed a new helper virus with a modified packaging signal and enhanced growth characteristics. We also redesigned the vector backbones by including noncoding adenovirus sequences adjacent to the right inverted terminal repeat and by incorporated a number of different segments of noncoding DNA of human origin as "stuffer." Comparison of these vectors showed that the nature of the stuffer sequence affects replication of the HD vector. Optimization of the system resulted in a more robust and consistent production of HD vectors with low helper contamination and high in vivo potency.

Adenoviral gene transfer of SERCA2a improves left-ventricular function in aortic-banded rats in transition to heart failure

In human and experimental models of heart failure, sarcoplasmic reticulum Ca(2+) ATPase (SERCA2a) activity is decreased, resulting in abnormal calcium handling. The disturbances in calcium metabolism have been shown to contribute significantly to the contractile dysfunction observed in heart failure. We investigated whether increasing SERCA2a expression can improve ventricular function in an animal model of heart failure obtained by creating ascending aortic constriction in rats. After 19-23 wk of banding during the transition from compensated hypertrophy to heart failure (documented by >25% decrease in fractional shortening), rats were randomized to receive either an adenovirus carrying the SERCA2a gene (Ad.SERCA2a, n = 13) or beta-galactosidase (Ad.betagal, n = 14) by using a catheter-based technique. The failing hearts infected with Ad. betagal were characterized by a significant decrease in SERCA2a expression and a decrease in SERCA2a activity compared with nonfailing sham-operated rats (n = 11). In addition, these failing hearts had reduced left-ventricular systolic pressure, maximal rate of left-ventricular pressure rise and decline (+dP/dt, -dP/dt), and rate of isovolumic relaxation (tau). Overexpression of SERCA2a restored both SERCA2a expression and ATPase activity to nonfailing levels. Furthermore, rats infected with Ad.SERCA2a had significant improvement in left-ventricular systolic pressure, +dP/dt, -dP/dt, and rate of isovolumic relaxation (tau) normalizing them back to levels comparable to sham-operated rats. In this study, we show that in an animal model of heart failure where SERCA2a protein levels and activity are decreased and severe contractile dysfunction is present, overexpression of SERCA2a in vivo restores both systolic and diastolic function to normal levels.

Vectors for gene therapy of cardiovascular disease

Several phase I/II clinical trials are currently ongoing in gene therapy of cardiovascular disease. Whereas the indications vary, including peripheral artery disease, ischemic heart disease, post-angioplasty restenosis, and vein graft failure, these trials are mostly based on the use of adenoviral vectors and nonviral vectors. Novel vectors aimed at improving the efficacy and safety of gene delivery in target organs, such as heart, skeletal muscle, vasculature, and liver, have been recently generated. Some of them have already been successfully validated in preclinical models of cardiovascular disease. This review focuses on the most recent advances in vector development that could substantially increase the spectrum of cardiovascular pathologies amenable to gene transfer-based treatments.