Helper-dependent Adenoviral Vectors Research Articles

IL4 gene delivery to the CNS recruits regulatory T cells and induces clinical recovery in mouse models of multiple sclerosis

Central nervous system (CNS) delivery of anti-inflammatory cytokines, such as interleukin 4 (IL4), holds promise as treatment for multiple sclerosis (MS). We have previously shown that short-term herpes simplex virus type 1-mediated IL4 gene therapy is able to inhibit experimental autoimmune encephalomyelitis (EAE), an animal model of MS, in mice and non-human primates. Here, we show that a single administration of an IL4-expressing helper-dependent adenoviral vector (HD-Ad) into the cerebrospinal fluid (CSF) circulation of immunocompetent mice allows persistent transduction of neuroepithelial cells and long-term (up to 5 months) CNS transgene expression without toxicity. Mice affected by chronic and relapsing EAE display clinical and neurophysiological recovery from the disease once injected with the IL4-expressing HD-Ad vector. The therapeutic effect is due to the ability of IL4 to increase, in inflamed CNS areas, chemokines (CCL1, CCL17 and CCL22) capable of recruiting regulatory T cells (CD4+CD69-CD25+Foxp3+) with suppressant functions. CSF delivery of HD-Ad vectors expressing anti-inflammatory molecules might represent a valuable therapeutic option for CNS inflammatory disorders.

Helper-dependent Adenovirus-mediated Short Hairpin RNA Expression in the Liver Activates the Interferon Response

The use of RNA interference has proven to be an effective means to study the function of genes. Constitutive synthesis of small interfering RNA molecules can be accomplished with the use of viral vectors expressing short hairpin RNA (shRNA). Binding of shRNA to the target mRNA promotes transcript degradation. So far, little is known about the effects that shRNA induce in vivo. To determine the feasibility of using helper-dependent adenoviral vectors for expression of shRNA in liver, we have designed an shRNA construct to mouse fabp5 (fatty acid-binding protein 5). Intravenous administration of this vector resulted in approximately 75% silencing of fabp5. Increasing the dose of vector did not result in higher levels of silencing, indicating that there is a threshold for the level of knockdown that can be achieved. Synthesis of high levels of shRNA molecules did not alter the levels of cellular micro-RNA, such as miR-122 and let-7a, suggesting that the exportin-5 pathway was not affected. However, high level shRNA expression resulted in activation of the interferon response. Thus, an important consideration when using shRNA-based vectors in vivo is to closely monitor signs of interferon-stimulated gene expression, since a narrow window exists between gene silencing efficacy and nonspecific effects.

Correction of Murine Hemophilia A and Immunological Differences of Factor VIII Variants Delivered by Helper-dependent Adenoviral Vectors

Bioengineering of the factor VIII (FVIII) molecule has led to the production of variants that overcome poor secretion and/or rapid inactivation. We tested six modified FVIII variants for in vivo efficacy by expressing them from helper-dependent adenoviral (HD-Ad) vectors. We constructed a wild-type (WT) variant, a B-domain-deleted (BDD) variant, a point mutant for improved secretion (F309S), a variant with a partial B-domain deletion for improved secretion (N6), a combination of the point mutant and partial BDD variant (F309N6), and an inactivation-resistant (IR8) FVIII variant. All the constructs expressed functional protein after injection of high-dose HD-Ad. Activity ranged from 20 to 50% with WT, to approximately 100% with the N6 and F309N6 variants. Interestingly, mice treated with N6 showed long-term FVIII activity and phenotypic correction for up to 74 weeks, with low anti-FVIII antibody titer. Importantly, the N6 variant was therapeutically efficacious even after a 50% reduction of viral dose, thereby indicating that transgene modification itself can improve the dose efficacy of HD-Ad. This finding is significant, because dose efficacy is a key factor in clinical application. In summary, bioengineering of the FVIII molecule may be an effective approach to improving the safety, immunogenicity, and efficacy of HD-Ad gene therapy in hemophilia A (HA).

Absence of an intrathecal immune reaction to a helper-dependent adenoviral vector delivered into the cerebrospinal fluid of non-human primates

Inflammation and immune reaction, or pre-existing immunity towards commonly used viral vectors for gene therapy severely impair long-term gene expression in the central nervous system (CNS), impeding the possibility to repeat the therapeutic intervention. Here, we show that injection of a helper-dependent adenoviral (HD-Ad) vector by lumbar puncture into the cerebrospinal fluid (CSF) of non-human primates allows long-term (three months) infection of neuroepithelial cells, also in monkeys bearing a pre-existing anti-adenoviral immunity. Intrathecal injection of the HD-Ad vector was not associated with any sign of systemic or local toxicity, nor by signs of a CNS-specific immune reaction towards the HD-Ad vector. Injection of HD-Ad vectors into the CSF circulation may thus represent a valuable approach for CNS gene therapy allowing for long-term expression and re-administration.

Successful Compensation for Dystrophin Deficiency by a Helper-dependent Adenovirus Expressing Full-length Utrophin

Helper-dependent adenovirus vector (AdV)-mediated full-length dystrophin expression leads to significant mitigation of the dystrophic phenotype of the mdx mouse. However, dystrophin, as a neoantigen, elicits antibody formation. As an alternative approach, we evaluated gene transfer of full-length murine utrophin, a functional homologue of dystrophin that is normally present only at the neuromuscular junction. A single injection in the tibialis anterior (TA) muscle of the helper-dependent adenovirus vector encoding utrophin provided very good transduction, with 58% of fibers demonstrating sarcolemmal utrophin expression in the neonates, and 35% utrophin-positive (Utr(+)) fibers in adults. The presence of utrophin prevented extensive necrosis in the neonates, halted further necrosis in the adults, and led to restoration of sarcolemmal expression of dystrophin-associated proteins up to 1 year after injection. Marked physiological improvement was observed in both neonates and adults. Neither increased humoral responses nor cellular immune responses were evident. However, there was a time-related decline of the initial high utrophin expression. Although viral DNA persisted in animals that were injected in the neonatal stage, viral DNA levels decreased in muscles of adult mice. These results demonstrate that although utrophin gene transfer leads to amelioration of the dystrophic phenotype, the effects are not sustained upon loss of utrophin expression.

Immune Response to Helper Dependent Adenoviral Mediated Liver Gene Therapy: Challenges and Prospects

Adenovirus-mediated gene therapy holds significant potential especially for applications requiring high levels of target tissue transduction. While significant advances in clinical adenoviral gene therapy applications have been made in cancer, the clinical translation of adenoviral gene replacement therapy for genetic disease has lagged. Encouragingly, advances in vector production have led to the development of Helper-Dependent ("gutted" or "high capacity") adenoviral vectors (HDV) deleted of all viral coding genes. HDV significantly reduces the chronic toxicity associated with early generation adenoviral vectors that has been most significant after systemic administration in both small and large animal models. However, the field remains confounded by innate immune responses inherent to adenovirus, and more generally, to the adaptive immune response to transgene. Together they decrease the effective therapeutic index for any particular treatment. This review summarizes the current advances toward understanding the decisive cell and molecular mechanisms underlying the acute toxicity to systemic HDV administration. We focus on the complex immune response and consequences of systemic vector delivery in the context of liver-directed monogenic disease therapy. Future development of interventions to avoid the innate immune response, including vector and pharmacologic manipulations, should further contribute to minimizing vector toxicity while maximizing the efficacy of systemic HDV gene transfer.

Helper‐dependent adenovirus for the gene therapy of proliferative retinopathies: stable gene transfer, regulated gene expression and therapeutic efficacy

Ocular neovascular disorders, such as diabetic retinopathy and age-related macular degeneration, are the principal causes of blindness in developed countries. Current treatments are of limited efficacy, whereas a therapy based on intraocular gene transfer of angiostatic factors represents a promising alternative. For the first time we have explored the potential of helper-dependent adenovirus (HD-Ad), the last generation of Ad vectors, in the therapy of retinal neovascularization. We first analyzed efficiency and stability of intraretinal gene transfer following intravitreous injection in mice. A HD-Ad vector expressing green fluorescent protein (GFP) under the control of the cytomegalovirus (CMV) promoter (HD-Ad/GFP) was compared with a first-generation (E1/E3-deleted) Ad vector carrying an identical GFP expression cassette (FG-Ad/GFP). We also constructed HD-Ad vectors expressing a soluble form of the VEGF receptor (sFlt-1) in a constitutive (HD-Ad/sFlt-1) or doxycycline (dox)-inducible (HD-Ad/S-M2/sFlt-1) manner and tested their therapeutic efficacy upon intravitreous delivery in a rat model of oxygen-induced retinopathy (OIR). HD-Ad/GFP promoted long-lasting (up to 1 year) transgene expression in retinal Müller cells, in marked contrast with the short-term expression observed with FG-Ad/GFP. Intravitreous injection of HD-Ad vectors expressing sFlt-1 resulted in detectable levels of sFlt-1 and inhibited retinal neovascularization by more than 60% in a rat model of OIR. Notably, the therapeutic efficacy of the inducible vector HD-Ad/S-M2/sFlt-1 was strictly dox-dependent. HD-Ad vectors enable stable gene transfer and regulated expression of angiostatic factors following intravitreous injection and thus are attractive vehicles for the gene therapy of neovascular diseases of the retina.

Efficacy of Helper-dependent Adenovirus Vector-mediated Gene Therapy in Murine Glycogen Storage Disease Type Ia

Genetic deficiency of glucose-6-phosphatase (G6Pase) underlies glycogen storage disease type Ia (GSD-Ia, also known as von Gierke disease; MIM 232200), an autosomal recessive disorder of metabolism associated with life-threatening hypoglycemia and growth retardation. We tested whether helper-dependent adenovirus (HDAd)-mediated hepatic delivery of G6Pase would lead to prolonged survival and sustained correction of the metabolic abnormalities in G6Pase knockout (KO) mice, a model for a severe form of GSD-Ia. An HDAd vector encoding G6Pase was administered intravenously (2 or 5 x 10(12)vector particles/kg) to 2-week-old (w.o.) G6Pase-KO mice. Following HDAd vector administration survival was prolonged to a median of 7 months, in contrast to untreated affected mice that did not survive past 3 weeks of age. G6Pase levels increased more than tenfold between 3 days and 28 weeks after HDAd injection (P < 0.03). The weights of untreated 2 w.o. G6Pase-KO mice were approximately half those of their unaffected littermates, and treatment stimulated their growth to the size of wild-type mice. Severe hypoglycemia and hypercholesterolemia, which are hallmarks of GSD-Ia both in humans and in mice, were also restored to normalcy by the treatment. Glycogen accumulation in the liver was markedly reduced. The efficacy of HDAd-G6Pase treatment in reversing the physiological and biochemical abnormalities associated with GSD-Ia in affected G6Pase-KO mice justifies further preclinical evaluation in murine and canine models of GSD-Ia.

Different modulation of cellular transcription by adenovirus 5, ΔE1/E3 adenovirus and helper-dependent vectors

One problem encountered in the use of adenoviral vectors for gene therapy is their toxicity. Although many studies have analyzed this question in vivo, few researches have investigated adenovirus vector effects at the cellular level using a large-scale approach. In particular, no such data are available for helper-dependent adenovirus vectors (HD), which are promising adenovirus vectors for clinical applications since they are devoid of all viral genes and can host large transgene cassettes. The present study used gene chips to examine (Affymetrix HG-U95Av2 interrogating 12,626 unique human transcripts) the effect on liver cells of HD vectors versus that of ΔE1/E3 adenovirus vector and wild type Adenovirus (Ad5). The effects of the ΔE1/E3 adenovirus and of HD vectors were comparable, and significantly milder than that of Ad5. Interestingly the expression signatures of ΔE1/E3 adenovirus and HD vectors were non-overlapping both at the single gene and the pathway level, suggesting specific and different interactions between the host cell and the two gene therapy vectors.

406. Long-Term Phenotypic Correction of Murine Hemophilia A and Immunological Differences of Bioengineered FVIII Variants Delivered by Helper-Dependent Adenoviral Vectors

406. Long-Term Phenotypic Correction of Murine Hemophilia A and Immunological Differences of Bioengineered FVIII Variants Delivered by Helper-Dependent Adenoviral Vectors

132. Gene Therapy for Duchenne Muscular Dystrophy by the Helper-Dependent Adenovirus Vector (HDAdv) - Mediated Full-Length Dystrophin Expression

132. Gene Therapy for Duchenne Muscular Dystrophy by the Helper-Dependent Adenovirus Vector (HDAdv) - Mediated Full-Length Dystrophin Expression

Erratum: Sustained phenotypic correction in a mouse model of hypoalphalipoproteinemia with a helper-dependent adenovirus vector

Correction to: Gene Therapy (2007) 14, 191–202. doi:10.1038/sj.gt.3302819 Since the above publication, the authors have noticed an error in the abbreviation of PMNs in Table 1. The correct table and abbreviation are shown below: The authors would like to apologise for this error.

Pseudo-hydrodynamic Delivery of Helper-dependent Adenoviral Vectors into Non-human Primates for Liver-directed Gene Therapy

Helper-dependent adenoviral vectors (HDAds) are attractive for liver-directed gene therapy because they can mediate long-term, high-level transgene expression without chronic toxicity. However, systemic delivery requires high vector doses for efficient hepatic transduction, resulting in dose-dependent acute toxicity. Clearly, strategies to improve hepatic transduction with low vector doses are needed. In this regard, we have previously shown that hydrodynamic injection of helper-dependent adenoviral vectors into mice results in increased hepatic transduction, reduced systemic vector dissemination, and reduced pro-inflammatory cytokines compared with conventional injection and thus has the potential to improve dramatically the therapeutic index of helper-dependent adenoviral vectors. Unfortunately, the rapid, large-volume injection used in this method cannot be applied to larger animals. Therefore, we have developed a novel balloon occlusion catheter-based method to mimic hydrodynamic injection of helper-dependent adenoviral vectors into non-human primates that does not require rapid, large-volume injection. Using a low, clinically relevant vector dose, this minimally invasive method results in high-efficiency hepatic transduction with minimal toxicity and stable long-term transgene expression for at least 413 days.

Carrier Cell–mediated Delivery of a Replication-competent Adenovirus for Cancer Gene Therapy

Carrier Cell–mediated Delivery of a Replication-competent Adenovirus for Cancer Gene Therapy

Toll-like Receptor 9 Triggers an Innate Immune Response to Helper-dependent Adenoviral Vectors

A major obstacle to the clinical application of systemic adenoviral gene replacement therapy is the host innate immune response. Although recent studies have attempted to characterize the cellular basis for this response to systemically administered helper-dependent adenoviral vector (HD-Ad), the underlying molecular components of the innate immune repertoire required to recognize the viral vector have yet to be identified. Here, we show that primary macrophages can sense HD-Ad vectors via the Toll-like Receptor 9 (TLR9) and respond by increasing pro-inflammatory cytokine secretion. Moreover, TLR9 sensing is involved in the rapid innate immune response to HD-Ad in vivo. TLR9 deficiency attenuates the innate immune response to HD-Ad, whereas TLR9 blockade reduces the acute inflammatory response after intravenous injection of the vector. Moreover, HD-Ad upregulates TLR9 gene expression independent of TLR9 function, suggesting that additional innate signaling pathways work cooperatively with TLR9. The identification of the components of the innate immune response to adenovirus will facilitate the development of combinatorial therapy directed at increasing the maximal tolerated dose of systemically delivered adenoviral vectors.

A Helper-Dependent Capsid-Modified Adenovirus Vector Expressing Adeno-Associated Virus Rep78 Mediates Site-Specific Integration of a 27-Kilobase Transgene Cassette

Random integration of viral gene therapy vectors and subsequent activation or disruption of cellular genes poses safety risks. Major efforts in the field are aimed toward targeting vector integration to specific sites in the host genome. The adeno-associated virus (AAV) Rep78 protein is able to target AAV integration to a specific site on human chromosome 19, called AAVS1. We studied whether this ability could be harnessed to achieve site-specific integration of a 27-kb transgene cassette into a model cell line for human hematopoietic cells (Mo7e). To deliver rep78 and the transgene to Mo7e cells, we used helper-dependent adenovirus (Ad) vectors containing Ad serotype 35 fiber knob domains (HD-Ad). An HD-Ad vector containing the rep78 gene under the control of the globin locus control region (LCR) (Ad.LCR-rep78) conferred Rep78 expression on Mo7e cells. Upon coinfection of Ad.LCR-rep78 with an HD-Ad vector containing a 27-kb globin-LCR-green fluorescent protein (GFP) transgene cassette flanked by AAV inverted terminal repeats (ITRs) (Ad.AAV-LCR-GFP), transduced cells were cloned and expanded (without selection pressure), and vector integration was analyzed in clones with more than 30% GFP-positive cells. Vector integration into the AAVS1 region was seen in 30% of analyzed integration sites, and GFP expression from these integrants was stable over time. Of the remaining integration sites, 25% were within the genomic globin LCR. In almost 90% of sites, transgene integration occurred via the Ad ITR. This indicates that rescue of the AAV ITR-flanked transgene cassette from Ad.AAV-LCR-GFP is not required for Rep78-mediated integration into AAVS1 and that free ends within the vector genome can be created by breaks within the Ad ITRs, whose structure is apparently recognized by cellular "nicking" enzymes. The finding that 55% of all analyzed integration sites were either within the AAVS1 or globin LCR region demonstrates that a high frequency of targeted integration of a large transgene cassette can be achieved in human hematopoietic stem cell lines.

Sustained phenotypic correction in a mouse model of hypoalphalipoproteinemia with a helper-dependent adenovirus vector

We examined the efficacy and host response to the adenovirus (Ad)-mediated delivery of human apolipoprotein A-I (APOA1) gene to the liver of APOA1(-/-) mice. Administration of a first-generation vector (FGAd-AI) resulted in a transient appearance of APOA1 in plasma and induced an anti-APOA1 antibody titer, whereas treatment with a helper-dependent vector (HDAd-AI) resulted in sustained APOA1 expression without inducing an antibody titer. With these results, we studied the effects of FGAd vectors on APOAI expression by HDAd-AI vector. Co-treatment with an FGAd vector inhibited HDAd-AI- mediated APOA1 expression independent of transgene cassettes, but only FGAd-AI induced a humoral response. Furthermore, APOA1 mRNA levels in mice co-treated with FGAd vectors were much lower than those expected from the vector copy number, suggesting that DNA of FGAd vectors interferes with the HDAd-AI vector's APOA1 promoter. A single treatment with an HDAd-AI vector produced a supraphysiological plasma APOA1 level that gradually declined to about half the normal human level over the course of 2 years, associated with a plasma cholesterol level that is persistently higher than that in controls. This investigation provides the proof of principle that liver-directed HDAd gene delivery is effective for the long-term phenotypic correction of monogenic hypoalphalipoproteinemia.

Effective High-Capacity Gutless Adenoviral Vectors Mediate Transgene Expression in Human Glioma Cells

Glioblastoma multiforme (GBM) is the most common subtype of primary malignant brain tumor. Although serotype 5 adenoviral vectors (Ads) have been used successfully in clinical trials for GBM, the capacity of Ads to infect human glioma cells and the expression of adenoviral receptors in GBM cells have been challenged. In this report, we studied the expression of three molecules that have been shown to mediate adenoviral entry into cells, i.e., coxsackie and adenovirus receptor (CAR), integrin αvβ3 (INT), and major histocompatibility complex class I (MHCI), in rodent glioma cell lines and low-passage primary cultures and cell lines from human GBM. We correlated levels of expression of CAR, INT, and MHCI with transduction efficiency elicited by several high-capacity helper-dependent adenoviral vectors (HC-Ads). Expression levels of adenoviral receptors were variable among the different GBM cells studied. HC-Ad-mediated therapeutic gene expression was efficient, ranging between 20 and 80% of the total target cells expressing the encoded transgenes. Our results show no correlation between the levels of CAR, INT, or MHCI molecules and the levels of transgene expression or the number of GBM cells transduced. We conclude that expression levels of adenoviral receptors do not predict their transduction efficiency or biological function.

Modulation of TNFα, a determinant of acute toxicity associated with systemic delivery of first-generation and helper-dependent adenoviral vectors

Understanding the determinants of the host innate immune response to systemic administration of adenoviral (Ad) vectors is critical for clinical gene therapy. Acute toxicity occurs within minutes to hours after vector administration and is characterized by activation of innate immune responses. Our data indicate that in mice, indicators of vector toxicity include elevations of cytokine levels, liver transaminase levels and thrombocytopenia. To discern potential targets for blunting this host response, we evaluated genetic factors in the host response to systemically administered first-generation Ad vectors (FGV) and helper-dependent Ad vectors (HDV) containing beta-galactosidase expression cassettes. A preliminary screen for modulation of vector-induced thrombocytopenia revealed no role for interferon-gamma, mast cells or perforin. However, vector-induced thrombocytopenia and interleukin 6 (IL-6) expression are less evident in tumor necrosis factor alpha (TNFalpha)-deficient mice. Moreover, we also demonstrated that TNFalpha blockade via antibody or huTNFR:Fc pretreatment attenuates both thrombocytopenia (>40% increase in platelet count) and IL-6 expression (>80% reduction) without affecting interleukin 12 , liver enzymes, hematological indices or vector transduction in a murine model. Our data indicate that the use of HDV, in combination with clinically approved TNFalpha immunomodulation, may represent an approach for improving the therapeutic index of Ad gene therapy for human clinical trials.

Helper-dependent adenoviral gene therapy mediates long-term correction of the clotting defect in the canine hemophilia A model.

Adenoviral vector-mediated gene therapy might have potential for long-term correction of the monogenic disease hemophilia A. In this study, we tested the efficacy of administering a helper-dependent adenoviral vector (HDV) designed for maximal liver-restricted canine factor VIII (cFVIII) expression on three out-bred hemophilia A dogs. Three FVIII-deficient animals from the University of North Carolina colony were injected with 1 x 10(12) (Dog A), and 3 x 10(12) (Dog B and C) vp kg(-1) helper-dependent adenoviral vector, and we performed systematic analysis of toxicity, persistence of therapeutic gene expression, and molecular analysis of gene transfer. We observed acute dose-dependent elevation in liver enzymes and thrombocytopenia after injection, although both were transient and resolved within 2 weeks. The whole blood clotting time (WBCT), plasma FVIII concentration, FVIII activity, and activated partial thromboplastin time in all animals improved significantly after treatment, and two animals receiving a higher dose reached near normal WBCT with low-level FVIII activity until terminal sacrifice at 3 months, and 2 years. Importantly, the treated dogs suffered no bleeding events after injection. Moreover, we observed persistent vector-specific DNA and RNA in liver tissue collected from one high-dose animal at days 18 and 79, and could not detect the formation of inhibitory antibodies. Although vector-associated toxicity remains an obstacle, a single injection of HDV led to long-term transgene expression and vector persistence in two FVIII-deficient animals with conversion of their severe phenotype to a moderate one.