A fiber-modified adenovirus co-expressing HSV-TK and Coli.NTR enhances antitumor activities in breast cancer cells

Breast cancers especially in late and metastatic stages remain refractory to treatment despite advances in surgical techniques and chemotherapy. Suicide gene therapy based on adenoviral technology will be promising strategies for such advanced diseases. We previously showed that co-expression of herpes simplex virus thymidine kinase (HSV-TK) and Escherichia coli nitroreductase (Coli.NTR) by an hTERT-driven adenovirus vector resulted in additive anti-tumor effects in breast cancer cells in vitro and in vivo. As many tumor tissue and cancer cells express low level of coxsackie-adenovirus receptor (CAR), which is the functional receptor for the fiber protein of human adenovirus serotype 5 (Ad5), novel Ad5 vectors containing genetically modifi ed fiber are attractive vehicles for achieving targeted gene transfer and improving suicide gene expression in these cancer cells. In the present study, we first built a simplified Ad5 vector platform for fiber modification and quick detection for gene transfer. Then a fiber-modified adenovirus vector containing an RGD motif in the HI loop of the fiber knob was constructed. After recombined with HSV-TK and Coli.NTR gene, this fiber-modified Ad5 vector (Ad-RGD-hT-TK/NTR) was compared with that of our previously constructed Ad5 vector (Ad-hT-TK/NTR) for its therapeutic effects in human breast cancer cell lines. The anti-tumor activity of Ad-RGD-hT-TK/NTR was significantly enhanced compared with Ad-hT-TK/NTR both in vitro and in vivo. This new vector platform provided a robust and simplified approach for capsid modification, and the fiber-modified Ad5 with double suicide genes under the control of hTERT promoter would be a useful gene therapy strategy for breast cancer.     

Efficient delivery and stable gene expression in a hematopoietic cell line using a chimeric serotype 35 fiber pseudotyped helper-dependent adenoviral vector

Certain human cell populations have remained difficult to infect with human adenovirus (Ad) serotype 5 because of their lack of coxsackievirus B-adenovirus receptor (CAR). Native adenovirus fiber compositions, although diverse, cannot infect all tissue types. Recently, a chimeric Ad5/35 fiber was created, which displays an altered tropism from Ad5. We incorporated this chimeric fiber into a helper-dependent (HD) adenovirus vector system and compared HD to E1-deleted (E1Delta) vectors by transgene expression, cell transduction efficiency, and cytotoxicity. K562 cells were infected approximately 50 times more efficiently with the chimeric Ad5/35 fiber compared with the Ad5 fiber. Short-term transgene expression was sustained longer from HD Ad5/35 than E1Delta Ad5/35 vector after in vitro infection of actively dividing K562 cells. Rapid loss of transgene expression from E1Delta Ad5/35 infection was not due to the loss of vector genomes, as determined by quantitative real-time PCR (QRT-PCR), or cytotoxicity, but rather through a putative silencing mechanism.     

An adenovirus vector with a chimeric fiber derived from canine adenovirus type 2 displays novel tropism

Many clinically relevant tissues are refractory to Ad5 transduction because of negligible levels of the primary Ad5 receptor, the coxsackie and adenovirus receptor (CAR). Thus, development of Ad vectors that display CAR-independent tropism could lead directly to therapeutic gain. The Toronto strain of canine adenovirus type 2 (CAV2) exhibits native tropism that is augmented by, but not fully dependent upon, CAR for cellular transduction. We hypothesized that an Ad5 vector containing the nonhuman CAV2 knob would provide expanded tropism and constructed Ad5Luc1-CK, an E1-deleted Ad5 vector encoding the fiber knob domain from CAV2. Ad5Luc1-CK gene delivery to CAR-deficient cells was augmented up to 30-fold versus the Ad5 control vector, and correlated with increased cell surface binding. Further, we confirmed the importance of cellular integrins to Ad5Luc1-CK transduction. Herein, we present the rationale, design, purification, and characterization of a novel tropism modified, infectivity-enhanced Ad vector.     

Generation of a replication-deficient recombinant human adenovirus type 35 vector using bacteria-mediated homologous recombination

The use of adenovirus type 35 (Ad35) as a vector in vaccine and gene therapy studies is promising due to its broad cell tropism and low seroprevalence in humans. However, to date, a simple and effective system for producing recombinant Ad35 (rAd35) has not been well developed. This report describes a two-plasmid Ad35-Easy system to facilitate the production of recombinant Ad35 (rAd35). The system employed the pAd35-shuttle vector for foreign gene transfer and the pAd35-backbone vector to provide the Ad35 genomic backbone. A 293-Ad35E1B cell line was used to trans-complement rAd35 replication. rAd35 plasmids were obtained through homologous recombination following co-transformation of E. coli BJ5183 cells with recombinant pAd35-shuttle vectors harboring foreign genes. rAd35 viruses were obtained directly by transfecting 293-Ad35E1B cells with foreign gene-containing rAd35 plasmids and the pAd35-backbone vector. The production of E1 deficient rAd35 was evaluated by transfecting the 293-Ad35E1B cells with the rAd35 plasmid containing the enhanced green fluorescent protein (EGFP) gene. The virus grew effectively at a yield comparable to that of wild type Ad35 in HEp2 cells, indicating that the Ad35-Easy system is an efficient method for rapid production of rAd35 in sufficient quantities for vaccine development or gene therapy.     

Separating fact from fiction: assessing the potential of modified adenovirus vectors for use in human gene therapy

One of the major hurdles to successful gene therapy of genetic and/or acquired disease is the ability to efficiently introduce a foreign gene into the tissue of interest and, in the case of some genetic diseases, achieve long-term expression of the transgene. Due to their ability to transduce a wide variety of cell types in a cell-cycle independent fashion, adenovirus (Ad)-based vectors have received considerable attention in recent years as delivery vehicles for multiple gene therapy applications. Effective use of early "first-generation" versions of these vectors was hampered by not only the induction of strong immune responses in the host to the Ad vector and transduced cells, but also to direct acute and chronic toxicity caused by the vector itself. Furthermore, transgene expression was typically transient, lasting only a few weeks. Despite these limitations, these vectors have been used in a number of human clinical trials, eliciting both interesting as well as controversial results, some of which are summarized herein. Because of these limitations, a number of advances in adenovirus "vectorology", manifested primarily as the development of multiply attenuated Ads and vectors deleted of all viral protein coding sequences, has resulted in vectors which retain all of the advantages of Ad vectors and, in addition, do not exhibit the deleterious characteristics associated with [E1-]deleted Ads. This review focuses on the current state of the art regarding the potential for human use of Ad-based vectors, and how the use of this vector continues to offer the potential for successful use as a gene delivery tool for the treatment of a great number of human genetic and non-genetic diseases.     

Inhibition of HIV-1 replication in alveolar macrophages by adenovirus gene transfer vectors

To assess the hypothesis that infection of alveolar macrophages (AM) with adenovirus (Ad) gene transfer vectors might prevent subsequent human immunodeficiency virus (HIV)-1 replication in AM, AM isolated from normal volunteers were infected with increasing doses of first generation (E1(-)) Ad vectors, followed 72 h later by infection with HIV-1(JRFL), an R5/M-tropic strain that preferentially uses the CCR5 coreceptor. As a measure of HIV-1 replication, p24 Ag was quantified by enzyme-linked imunosorbent assay in supernatants on Days 4 to 14 after HIV-1infection. Pretreatment of the AM with an Ad vector resulted in a dose- and time-dependent suppression of subsequent HIV-1 replication. The Ad vector inhibition of HIV-1 replication was independent of the transgene in the Ad vector expression cassette and E4 genes in the Ad backbone. Moreover, it did not appear to be secondary to a soluble factor released by the AM, nor was it overridden by the concomitant transfer of the CCR5 or CXCR4 receptors to the AM before HIV-1 infection. These observations have implications regarding pulmonary host responses associated with HIV-1 infection, as well as possibly uncovering new therapeutic strategies against HIV-1 infection.     

Development of a recombinant adenovirus vector production system free of replication-competent adenovirus by utilizing a packaging size limit of the viral genome

In a conventional adenovirus (Ad) vector production method using 293 cells, homologous recombination between Ad vector DNA and 293 cell-derived Ad E1 DNA occurs with low efficiency, resulting in the generation of replication-competent adenovirus (RCA). RCA can induce the spread of replication-incompetent Ad vectors, leading to unexpected tissue damage. In order to overcome this problem, we developed an Ad vector production system free of RCA generation by utilizing the Ad packaging size limit of the viral genome. It is well known that up to approximately 105% (37.7 kb) of the wild-type genome (35.9 kb) can be packaged in the Ad virion. We designed the Ad vector genome by insertion of a transgene expression cassette into the E3 region, such that homologous recombination between the Ad vector DNA and 293 cell-derived Ad E1 DNA would produce an Ad vector genome that exceeds in the size of the packaging limit. In accord with our strategy, no RCA generation was observed during the passages when we used the E1 (3.2kb)-deleted Ad vectors containing a more than 3.0-kb transgene expression cassette in the E3 region. In contrast, the E1 (3.2kb)-deleted Ad vectors, which retain 37.7 kb of the viral genome and have an insertion of a 2.1-kb transgene expression cassette in the E3 region, generated RCA, although RCA derived from this Ad vector exceeded the packaging size limit (105.0%). These results suggest that RCA generation can be avoided when the genome size of RCA is more than 108.3% (38.9 kb) of the wild-type Ad genome. This Ad vector production system generates safe, easy, and efficient Ad vector stock for both basic study as well as clinical research.     

Encapsidated adenovirus minichromosomes allow delivery and expression of a 14 kb dystrophin cDNA to muscle cells

Adenovirus-mediated gene transfer to muscle is a promising technology for gene therapy of Duchenne muscular dystrophy (DMD). However, currently available recombinant adenovirus vectors have several limitations, including a limited cloning capacity of approximately 8.5 kb, and the induction of a host immune response that leads to transient gene expression of 3-4 weeks in immunocompetent animals. Gene therapy for DMD could benefit from the development of adenoviral vectors with an increased cloning capacity to accommodate a full-length (approximately 14 kb) dystrophin cDNA. This increased capacity should also accommodate gene regulatory elements to achieve expression of transduced genes in a tissue-specific manner. Additional vector modifications that eliminate adenoviral genes, expression of which is associated with development of a host immune response, might greatly increase long-term expression of virally delivered genes in vivo. We have constructed encapsidated adenovirus minichromosomes theoretically capable of delivering up to 35 kb of non-viral exogenous DNA. These minichromosomes are derived from bacterial plasmids containing two fused inverted adenovirus origins of replication embedded in a circular genome, the adenovirus packaging signals, a beta-galactosidase reporter gene and a full-length dystrophin cDNA regulated by a muscle-specific enhancer/promoter. The encapsidated minichromosomes are propagated in vitro by trans-complementation with a replication-defective (E1 + E3 deleted) helper virus. We show that the minichromosomes can be propagated to high titer (> 10(8)/ml) and purified on CsCl gradients due to their buoyancy difference relative to helper virus. These vectors are able to transduce myogenic cell cultures and express dystrophin in myotubes. These results suggest that encapsidated adenovirus minichromosomes may be useful for gene transfer to muscle and other tissues.      

Development of adenovirus serotype 35 as a gene transfer vector

While 51 human adenoviral serotypes have been identified to date, the vast majority of adenoviral vectors designed for gene transfer have been generated in the adenovirus serotype 5 (Ad5) backbone. Viral infections caused by Ad5 are endemic in most human populations and the majority of humans carry preexisting humoral and/or cellular immunity to Ad5 which may severely limit the use of Ad5-based vectors for gene therapy applications. To circumvent this preexisting Ad5 immunity, we have identified Ad35 as an alternative adenoviral serotype to which the majority of humans do not have neutralizing antibodies. Importantly, Ad35 can be grown to high titers with a low particle-to-PFU ratio. As a prerequisite for the development of Ad35 for use as a gene transfer vector, a genome organization map was constructed using the available Ad35 sequence information, and E1a-deficient Ad35 vectors encoding marker genes were generated. Ad35 biodistribution in mice was assessed following intravenous administration and compared with that of Ad5. Extremely low levels of Ad35 were detected in all organs evaluated, including liver, lung, spleen, and bone marrow, while Ad5 displayed high transduction of these organs. Due to the lack of Ad35 liver tropism, minimal hepatotoxicity was observed in mice treated with Ad35. Furthermore, the half-life of Ad35 in mouse blood was found to be two to three times longer than that of Ad5. These data suggest that either mice do not express the Ad35 cell surface receptor or that Ad35 does not efficiently transduce mouse cells in vivo following systemic delivery. Therefore, to begin to elucidate the Ad35 cell entry mechanisms, in vitro competition studies were performed. These data demonstrated that Ad35 cell entry is CAR independent, and may involve protein(s) expressed on most human cells.     

Insertion of CTCF-binding sites into a first-generation adenovirus vector reduces the innate inflammatory response and prolongs transgene expression

We have made improvements to E1-deleted adenovirus (Ad) transducing vectors that both substantially reduce the innate inflammatory response provoked by the virus in BALB/c mouse ears and increase the duration of expression of the GFP transgene in BALB/c mouse liver. These improvements result from testing the hypothesis that induction of strong innate responses is primarily a result of the powerful enhancer contained within the strong CMV promoter activating expression of Ad genes retained within the vector. A DNA fragment containing four CTCF-binding sites, which was expected to act as a chromatin insulator, was introduced 5′, 3′, or both 5′ and 3′ of a CMV-GFP cassette in an attempt to reduce activation of Ad gene expression by the enhancer. The presence of this sequence in any of the configurations led to reduction of the innate immune response, as assayed by mouse ear swelling, to the low level induced by a virus deleted for the E1 region and carrying no introduced sequence. In addition, the duration of GFP expression in the liver more than doubled. The prolonged GFP expression indicates that GFP does not play the limiting role in shutting down vector expression. The CTCF-binding sequence introduced appears to act as a chromatin insulator in Ad DNA, but position-independence of the elements in reducing the innate immune response indicate unanticipated complexities in the mechanism by which Ad vectors induce innate immune responses.     

A mosaic adenovirus possessing serotype Ad5 and serotype Ad3 knobs exhibits expanded tropism

The efficiency of cancer gene therapy with recombinant adenoviruses based on serotype 5 (Ad5) has been limited partly because of variable, and often low, expression by human primary cancer cells of the primary cellular-receptor which recognizes the knob domain of the fiber protein, the coxsackie and adenovirus receptor (CAR). As a means of circumventing CAR deficiency, Ad vectors have been retargeted by utilizing chimeric fibers possessing knob domains of alternate Ad serotypes. We have reported that ovarian cancer cells possess a primary receptor for Ad3 to which the Ad3 knob binds independently of the CAR-Ad5 knob interaction. Furthermore, an Ad5-based chimeric vector, designated Ad5/3, containing a chimeric fiber proteins possessing the Ad3 knob, demonstrates CAR-independent tropism by virtue of targeting the Ad3 receptor. Based on these findings, we hypothesized that a mosaic virus possessing both the Ad5 knob and the Ad3 knob on the same virion could utilize either primary receptor, resulting in expanded tropism. In this study, we generated a dual-knob mosaic virus by coinfection of 293 cells with Ad5-based and Ad5/3-based vectors. Characterization of the resultant virions confirmed the incorporation of both Ad5 and Ad3 knobs in the same particle. Furthermore, this mosaic virus was able to utilize either receptor, CAR and the Ad3 receptor, for virus attachment to cells. Enhanced Ad infectivity with the mosaic virus was shown in a panel of cell lines, with receptor profiles ranging from CAR-dominant to Ad3 receptor-dominant. Thus, this mosaic virus strategy may offer the potential to improve Ad-based gene therapy approaches by infectivity enhancement and tropism expansion.     

Attenuation of Replication-Competent Adenovirus Serotype 26 Vaccines by Vectorization

Replication-competent adenovirus (rcAd)-based vaccine vectors may theoretically provide immunological advantages over replication-incompetent Ad vectors, but they also raise additional potential clinical and regulatory issues. We produced replication-competent Ad serotype 26 (rcAd26) vectors by adding the E1 region back into a replication-incompetent Ad26 vector backbone with the E3 or E3/E4 regions deleted. We assessed the effect of vectorization on the replicative capacity of the rcAd26 vaccines. Attenuation occurred in a stepwise fashion, with E3 deletion, E4 deletion, and human immunodeficiency virus type 1 (HIV-1) envelope (Env) gene insertion all contributing to reduced replicative capacity compared to that with the wild-type Ad26 vector. The rcAd26 vector with E3 and E4 deleted and containing the Env transgene exhibited 2.7- to 4.4-log-lower replicative capacity than that of the wild-type Ad26 in vitro. This rcAd26 vector is currently being evaluated in a phase 1 clinical trial. Attenuation as a result of vectorization and transgene insertion has implications for the clinical development of replication-competent vaccine vectors.     

7型腺病毒疫苗株序列测定及其六邻体特性分析

目的 完成7型腺病毒疫苗株(Ad7v)的全序列测定并阐明其六邻体特征。方法 克隆Ad7v基因组17．5～68．0mu片段，应用Sanger双脱氧法进行DNA序列测定，将编码六邻体蛋白的核苷酸序列输入GenBank数据库中，获得录入号为AF515814。用CLUSTAL.V软件比较Ad7v与其他亚组及同一亚组腺病毒的六邻体蛋白的同源性，分析其抗原性的差异，同时用RasMol2．71软件预测Ad7v六邻体三维结构。结果 AdTv17．5～68．0mu由17596个碱基组成。这段基因r链主要编码晚期基因L1、L2和L3，L链编码E2的一部分。六邻体编码多肽位于L3区，由934个氨基酸残基组成，与其他9个已知的六邻体蛋白序列进行多序列同源性比较，发现Ad7／疫苗株与其他亚组腺病毒的同源性为86．8％(Ad4)～78．5％(Ad5)。在同一亚组中，Ad7疫苗株与Ad3同源性最高，高达95．1％。可变序列主要集中在7个高变区(HVRs)，根据Ad2六邻体三维结构模型预测Ad7六邻体三维结构，发现可变区大部分位于六邻体顶端的I1和I2环中。结论 完成了AdTv的全序列分析，其六邻体序列与Ad5、Ad2等其他亚组病毒有很大差异，这一结果为构建新型腺病毒载体打下了基础。     

Adenovirus type 5 pseudotyped with adenovirus type 37 fiber uses sialic acid as a cellular receptor

For purposes of gene therapy, the tropism of adenovirus (Ad) serotype 5 vectors can be altered with fibers derived from alternative serotypes. However, there is currently limited information available on the cellular receptors used by the approximately 51 known Ad serotypes. Recently, alpha(2-->3)-linked sialic acid (2,3-SA) has been implicated as the cellular receptor for wild-type Ad37. However, some studies have demonstrated that wild-type Ad37 uses a 50-kDa protein and not sialic acid as its primary receptor for binding of human conjunctival cells. The sialic acid receptor has also been shown not to play a major role in the infection of these cells by an Ad5 virion pseudotyped with Ad37 fiber (Ad5.GFP.DeltaF/37F). In this study, we demonstrate that a similar virus (Ad5F37) can indeed use alpha(2-->3)-linked sialic acid as a cellular receptor. We also find that the receptor used by Ad5F37 is sensitive to proteases and that Ad5F37 can use integrin more efficiently than sialic acid for cell entry. Unlike Ad5 vectors, Ad5F37 does not efficiently employ the coxsackie and adenovirus receptor (CAR) to infect cells. Similar to Ad5, Ad5F37 infection of cells that form tight junctions can be enhanced by ethylenediaminetetraacetic acid (EDTA). These results have implications in the design of pseudotyped adenovirus vectors for gene therapy and may have particular use in the treatment of diseases involving breakdown of the blood-retinal barrier.     

Hexon-specific PEGylated adenovirus vectors utilizing avidin-biotin interaction

PEGylation of recombinant adenovirus (Ad) vectors is a promising approach for not only evasion from neutralizing anti-Ad antibodies and uptake by phagocytic cells, but also prolongation of the blood retention time of Ad vectors after systemic administration. However, the conventional PEGylation leads to significant reduction in the transduction activity of Ad vectors, probably because PEG is nonspecifically conjugated to the Ad capsid protein and inhibits the binding of Ad vectors to the primary receptor, coxsackievirus-adenovirus receptor (CAR). In order to PEGylate an Ad vector without significant reduction in the transduction activity, the biotin-binding peptide (BAP) was inserted into the hypervariable region (HVR) 5 of the hexon, which is not involved in the binding to CAR, and PEG was then specifically conjugated to the hexon HVR5 via avidin-biotin interaction. In vitro transduction experiments demonstrated that the hexon-specific PEGylation did not cause an apparent reduction in the transduction efficiency of the Ad vector, although the insertion of the BAP into the HVR5 itself reduced the transduction efficiency by 50-fold, compared with the conventional Ad vector, in the absence of anti-Ad serum. In the presence of anti-Ad serum, the transduction with the Ad vector with the BAP in the hexon HVR5 was significantly blocked; however, anti-Ad serum only slightly inhibited the transduction with the hexon-specifically PEGylated Ad vector (Ad-BAP/Bio/Avi/Bio-PEG-L2). Intravenous administration of Ad-BAP/Bio/Avi/Bio-PEG-L2 resulted in prolonged blood retention, significant reduction in the transduction in the liver, and accumulation in the tumor; however, unexpectedly, the transduction efficiency of Ad-BAP/Bio/Avi/Bio-PEG-L2 in the tumor was almost at the background level.     

Analysis of adenovirus gene transfer into adult neural stem cells

Adult neural stem cells (aNSCs) represent an attractive source for the production of specific types of neurons in degenerative CNS diseases and for the development of new regenerative gene therapies. However, the use of adult NSCs for transplantation and gene replacement strategies requires efficient gene expression in the cells. Due to the low pathogenicity of adenovirus (Ad) for humans, its large delivery capacity, and long-term transgene expression, Ad vectors are widely used. Here, we tested the potential of the Ad vector system to transduce adult NSCs. Analysis of Ad receptor expression in primary aNSCs revealed a complete lack of the coxsackie-adenovirus receptor and no or low expression of alphanu- and beta5-integrins, respectively, on mRNA and protein level. Consistently, transduction at different multiplicities of infection using an Ad vector expressing the enhanced green fluorescent protein (GFP) showed that adult NSCs are particularly resistant to Ad infection even at highest MOI (1000) in contrast to differentiated types of neural cells.     

Stable transduction of large DNA by high-capacity adeno-associated virus/adenovirus hybrid vectors

Viral vectors with high cloning capacity and host chromosomal integration ability are in demand for the efficient and permanent genetic modification of target cells with large DNA molecules. We have generated a hybrid gene transfer vehicle consisting of recombinant adeno-associated virus (AAV) replicative intermediates packaged in adenovirus (Ad) capsids. This arrangement allows cell cycle-independent nuclear delivery of recombinant AAV genomes with lengths considerably above the maximum size (i.e., 4.7 kb) that can be accommodated within AAV capsids. Here we show that high-capacity AAV/Ad hybrid vector gene transfer mediates cellular genomic integration of large fragments of foreign DNA and accomplishes stable long-term transgene expression in rapidly proliferating cells. Southern blot and polymerase chain reaction analyses of chromosomal DNA extracted from clones of stably transduced cells revealed that most of them contained a single copy of the full-length hybrid vector genome with AAV inverted terminal repeat (ITR) sequences at both ends. The high-capacity AAV/Ad hybrid vector system can thus be used for the transfer and expression of transgenes that cannot be delivered by conventional integrating viral vectors.     

Local adenovirus-mediated CTLA4-immunoglobulin expression suppresses the immune responses to adenovirus vectors in the brain

The effect of local administration of two adenovirus vectors, one of which expressed CTLA4-immunoglobulin (AdCTLA), which blocks the B7-CD28 co-stimulatory pathway of T cell activation in the inflammatory response to adenovirus vectors was investigated. Mice injected with AdCTLA and an E1-deleted adenovirus vector that encodes the lacZ gene (AdRL) into the brain showed inflammatory cell infiltration from the early phase until day 6 after injection that was not different from that seen in control mice injected with an E1-deleted adenovirus vector containing no transgene (Ad0) and AdRL. After day 6 the inflammation in the control mice increased, peaked by day 15 and then decreased gradually but persisted until day 60. By contrast, in mice treated with AdCTLA and AdRL the inflammation, especially T cell infiltration, was suppressed after day 15. The anti-adenovirus antibody titer increased gradually until day 60 in the Ad0-AdRL control group, and whereas the mice injected with AdCTLA and AdRL showed lower anti-adenovirus antibody titers than the control group mice after day 15. Neutralizing antibody was not detected in either group. Expression of beta-galactosidase, the gene product of AdRL, at the injection site in the striatum and corpus callosum peaked on day 6 and remained until day 60 although it was very low in both groups; beta-galactosidase expression was similar in the two groups in spite of the difference in the degree and extent of the local immune response in the brain. This study demonstrated that the injection of an adenovirus vector expressing CTLA4-immunoglobulin into the brain suppressed not only local cell infiltration in the brain but also reduced the humoral immune response to adenovirus vectors.