Kahori Shimizu

Adenovirus Vector-Derived VA-RNA-Mediated Innate Immune Responses

The major limitation of the clinical use of replication-incompetent adenovirus (Ad) vectors is the interference by innate immune responses, including induction of inflammatory cytokines and interferons (IFN), following in vivo application of Ad vectors. Ad vector-induced production of inflammatory cytokines and IFNs also results in severe organ damage and efficient induction of acquired immune responses against Ad proteins and transgene products. Ad vector-induced innate immune responses are triggered by the recognition of Ad components by pattern recognition receptors (PRRs). In order to reduce the side effects by Ad vector-induced innate immune responses and to develop safer Ad vectors, it is crucial to clarify which PRRs and which Ad components are involved in Ad vector-induced innate immune responses. Our group previously demonstrated that myeloid differentiating factor 88 (MyD88) and toll-like receptor 9 (TLR9) play crucial roles in the Ad vector-induced inflammatory cytokine production in mouse bone marrow-derived dendritic cells. Furthermore, our group recently found that virus associated-RNAs (VA-RNAs), which are about 160 nucleotide-long non-coding small RNAs encoded in the Ad genome, are involved in IFN production through the IFN-β promoter stimulator-1 (IPS-1)-mediated signaling pathway following Ad vector transduction. The aim of this review is to highlight the Ad vector-induced innate immune responses following transduction, especially VA-RNA-mediated innate immune responses. Our findings on the mechanism of Ad vector-induced innate immune responses should make an important contribution to the development of safer Ad vectors, such as an Ad vector lacking expression of VA-RNAs.

Suppression of leaky expression of adenovirus genes by insertion of microRNA-targeted sequences in the replication-incompetent adenovirus vector genome

Leaky expression of adenovirus (Ad) genes occurs following transduction with a conventional replication-incompetent Ad vector, leading to an induction of cellular immunity against Ad proteins and Ad protein-induced toxicity, especially in the late phase following administration. To suppress the leaky expression of Ad genes, we developed novel Ad vectors by incorporating four tandem copies of sequences with perfect complementarity to miR-122a or miR-142-3p into the 3′-untranslated region (UTR) of the E2A, E4, or pIX gene, which were mainly expressed from the Ad vector genome after transduction. These Ad vectors easily grew to high titers comparable to those of a conventional Ad vector in conventional 293 cells. The leaky expression of these Ad genes in mouse organs was significantly suppressed by 2- to 100-fold, compared with a conventional Ad vector, by insertion of the miRNA-targeted sequences. Notably, the Ad vector carrying the miR-122a–targeted sequences into the 3′-UTR of the E4 gene expressed higher and longer-term transgene expression and more than 20-fold lower levels of all the Ad early and late genes examined in the liver than a conventional Ad vector. miR-122a–mediated suppression of the E4 gene expression in the liver significantly reduced the hepatotoxicity which an Ad vector causes via both adaptive and non-adaptive immune responses.

Quantitative analysis of the leaky expression of adenovirus genes in cells transduced with a replication-incompetent adenovirus vector.

Theoretically, adenovirus (Ad) genes should not be expressed following transduction with a replication-incompetent Ad vector because the E1A gene, which is essential for the expression of other viral gene, is deleted in a replication-incompetent Ad vector. However, leaky expression of viral genes is known to occur following transduction with an E1-deleted Ad vector, leading to an induction of cellular immunity against Ad proteins. To date, no detailed analysis of the leaky expression profiles of Ad genes has been performed. In this study, we systematically examined the expression profiles of Ad genes in cells following transduction with a replication-incompetent Ad vector (Ad-L2) at multiplicities of infection (MOIs) of 10 and 100 using real-time RT-PCR. Significant expression was found for the E4 and pIX genes following transduction with Ad-L2 in cultured cells. The expression levels of the E4 and pIX genes were approximately 30- to 600-fold lower than those of the transgene (firefly luciferase), and 50- to 5000-fold lower than those of the E4 and pIX genes following transduction at the same MOI with the wild-type Ad. Unexpectedly, expression levels of the major capsid proteins were approximately the same as, or even slightly above, the background levels (Ad gene expression levels in mock-transduced cells). This study provides valuable information for the design of a safe and efficient replication-incompetent Ad vector.

NF-κB promotes leaky expression of adenovirus genes in a replication-incompetent adenovirus vector

The replication-incompetent adenovirus (Ad) vector is one of the most promising vectors for gene therapy; however, systemic administration of Ad vectors results in severe hepatotoxicities, partly due to the leaky expression of Ad genes in the liver. Here we show that nuclear factor-kappa B (NF-κB) mediates the leaky expression of Ad genes from the Ad vector genome, and that the inhibition of NF-κB leads to the suppression of Ad gene expression and hepatotoxicities following transduction with Ad vectors. Activation of NF-κB by recombinant tumor necrosis factor (TNF)-α significantly enhanced the leaky expression of Ad genes. More than 50% suppression of the Ad gene expression was found by inhibitors of NF-κB signaling and siRNA-mediated knockdown of NF-κB. Similar results were found when cells were infected with wild-type Ad. Compared with a conventional Ad vector, an Ad vector expressing a dominant-negative IκBα (Adv-CADNIκBα), which is a negative regulator of NF-κB, mediated approximately 70% suppression of the leaky expression of Ad genes in the liver. Adv-CADNIκBα did not induce apparent hepatotoxicities. These results indicate that inhibition of NF-κB leads to suppression of Ad vector-mediated tissue damages via not only suppression of inflammatory responses but also reduction in the leaky expression of Ad genes.

Quantitative Analysis of Virus-associated RNAI Expression following Transduction with a Replication-incompetent Adenovirus Vector In Vitro and In Vivo

The adenovirus (Ad) genome encodes one or two non-coding small RNAs called virus-associated (VA)-RNAs, that are transcribed by polymerase III and support Ad replication. As previously reported, a replication-incompetent Ad vector, which is widely used in not only gene therapy studies, including clinical trials, but also basic researches as a gene delivery vehicle, as well as wild-type Ad (WT-Ad) express VA-RNAs, and VA-RNAs activate innate immunity, including the production of type I interferons. In addition, VA-RNAs perturb cellular microRNA (miRNA) expression profiles via competitive inhibition of key components involved in the miRNA maturation pathway. Although these characteristics of VA-RNAs might negatively affect the application of Ad vectors, VA-RNA expression profiles following transduction with an Ad vector have been not fully examined. In this study, we quantitatively analyzed the expression profiles of VA-RNAI, which is a major species of VA-RNAs, following transduction with Ad vectors in vitro and in vivo using real-time RT-PCR. The VA-RNAI expression levels in the cells transduced with a conventional Ad vector expressing luciferase (Ad-CAL2) at a multiplicity of infection (MOI) of 100 were approximately 2000- to 3000-fold lower than those infected with WT-Ad at the same MOI at 48 h after treatment. The expression levels of VA-RNAI in the mouse liver following administration with Ad-CAL2 were approximately 600-fold lower than those following administration with WT-Ad at 48 h post-administration. miRNA-mediated suppression of leaky expression of the Ad E4 genes resulted in about five-fold reduction in the VA-RNAI copy numbers in the liver following systemic administration in mice. These data provide informative clues for the development of novel safer Ad vectors.

Evaluation of Transduction Properties of an Adenovirus Vector in Neonatal Mice

In gene therapy for congenital disorders, treatments during neonate and infant stages are promising. Replication-incompetent adenovirus (Ad) vectors have been used in gene therapy studies of genetic disorders; however, the transduction properties of Ad vectors in neonates and infants have not been fully examined. Accordingly, this study examined the properties of Ad vector-mediated transduction in neonatal mice. A first-generation Ad vector containing a cytomegalovirus (CMV) promoter-driven luciferase expression cassette was administered to neonatal mice on the second day of life via retro-orbital sinus. The highest Ad vector genome copy numbers and transgene expression were found in the neonatal liver. The neonatal heart exhibited the second highest levels of transgene expression among the organs examined. There was an approximately 1500-fold difference in the transgene expression levels between the adult liver and heart, while the neonatal liver exhibited only an approximately 30-fold higher level of transgene expression than the neonatal heart. A liver-specific promoter for firefly luciferase expression conferred a more than 100-fold higher luciferase expression in the liver relative to the other organs. No apparent hepatotoxicity was observed in neonatal mice following Ad vector administration. These findings should provide valuable information for gene therapy using Ad vectors in neonates and infants.

111. Efficient Transduction in Neonatal Mice via Systemic Administration of an Adenovirus Vector

An adenovirus (Ad) vector is widely used as a gene delivery vector due to their various advantages. An Ad vector is applicable to innate genetic diseases, which are crucial targets of gene therapy. Patients of several innate genetic disorders often display symptoms in their early stage of life and are danger of death without any treatments. Radical treatments in infant ages are required in such patients. Gene therapy in neonates and infants is promising for such innate genetic disorders. In addition, although immune responses to an Ad vector hamper Ad vector-mediated transduction in adults, it is expected that such inhibitions do not occur in neonates and infants because of their immature immunity; however, transduction properties of Ad vectors in neonates and infants have not been fully examined. In this study, Ad vector-mediated transduction properties in neonatal mice were examined.A first-generation Ad vector containing a CMV promoter-driven firefly luciferase expression cassette was administered to newborn mice on the second day of life at a dose of 5.9×1011 infectious unit (IFU)/kg (this titer is equal to 1010 IFU/5-weeks old mice) via retro-orbital sinus. First, biodistribution of an Ad vector in neonatal mice was investigated 2 days after administration. As is the case with adult mice, the highest copy numbers of Ad vector genome were found in the liver among the organs. The liver also showed the highest levels of luciferase expression among the organs in neonates, although the transduction efficiency in the neonatal liver was approximately 5-fold lower than that in the adult liver. On the other hand, neonatal mice exhibited 10-fold higher levels of luciferase expression in the heart than adult mice. While approximately more than 1000-fold higher transduction efficiency was found in the adult liver, compared with the adult heart, the neonatal liver exhibited only 30-fold higher transduction efficiency than the neonatal heart. In order to achieve liver-specific transduction, a liver-specific promoter (a fusion promoter composed of apolipoprotein E enhancer, the hepatocyte control region, and human alpha 1-antitrypsin promoter) was incorporated into an Ad vector. The Ad vector containing the liver-specific promoter mediated almost 100-fold higher transduction efficiencies in the liver, compared with those in the other organs. Second, Ad vector-induced hepatotoxicity in neonatal mice was evaluated. Obvious elevation in serum alanine aminotransferase (ALT) activity in neonatal mice was not observed within 2 weeks following Ad vector administration, indicating that this dose of Ad vectors did not provoke significant hepatotoxicity in neonatal mice. In addition, while anti-Ad antibodies were strongly induced in the serum of adult mice on 21 days post Ad vector injection, almost background levels of anti-Ad antibodies were detected in neonatal mice. These results provide crucial information for gene therapy in neonates and infants.