Shinnosuke Kurachi

PEGylated adenovirus vectors containing RGD peptides on the tip of PEG show high transduction efficiency and antibody evasion ability

PEGylation of adenovirus vectors (Ads) is an attractive strategy in gene therapy. Although many types of PEGylated Ad (PEG‐Ads), which exhibit antibody evasion activity and long plasma half‐life, have been developed, their entry into cells has been prevented by steric hindrance by polyethylene glycol (PEG) chains. Likewise, sufficient gene expression for medical treatment could not be achieved.

Characterization of capsid-modified adenovirus vectors containing heterologous peptides in the fiber knob, protein IX, or hexon.

Adenovirus (Ad) vectors are widely used in gene therapy and in vitro/in vivo gene transfer because of their high transduction efficiency. However, Ad vector application in the gene therapy field is limited by poor transduction into cells not expressing the primary receptor, coxsackievirus and adenovirus receptor. To overcome this problem, several types of capsid-modified Ad vectors have been developed. The HI loop or C-terminus of the fiber knob, the C-terminus of the protein IX (pIX) and the hypervariable region 5 of the hexon are promising candidate locations for displaying foreign peptide sequences. In the present study, we constructed Ad vectors in which each of the above region was modified by a simple in vitro ligation-based method, and examined the characterization of each Ad vector containing the FLAG tag (DYKDDDDK) or RGD (CDCRGDCFC) peptide. Enzyme-linked immunosorbent assay examining the surface expression of foreign peptides on the virus suggested that foreign peptides are exposed on virion surfaces in all types vectors and that the hexon was the most efficiently reacted, reflecting the copy number of the modification. However, in the case of the transduction efficiency of Ad vectors containing the RGD peptides, the modification of pIX and the hexon showed no effect. The modification of the HI loop of the fiber knob was the most efficient, followed by the modification of the C-terminus region of the fiber knob. These comparative analyses, together with a simple construction method for each modified Ad vector, could provide basic information for the generation of capsid-modified Ad vectors.

Induction of type I interferon by adenovirus-encoded small RNAs

Transduction with replication-incompetent recombinant adenovirus (Ad) vectors results in a rapid activation of innate immune responses, such as inflammatory cytokine production and subsequent tissue damage. The precise mechanisms of the innate immune responses induced by Ad vectors remain to be clarified. Possible components of Ad vectors that activate innate immune responses are the capsid protein, the viral genome (DNA), and viral transcripts. In the present study, we demonstrate that virus-associated RNAs (VA-RNAs), which are small RNAs transcribed by RNA polymerase III, induce the production of type I IFN (IFN-α and IFN-β), but they do not induce the production of inflammatory cytokines (IL-6 and IL-12), in mouse embryonic fibroblasts (MEFs) and granulocyte-macrophage colony-stimulating factor–generated bone marrow-derived dendritic cells (GM-DCs). We also show that IFN-β promoter stimulator-1 is involved in VA-RNA–dependent IFN-β production in MEFs and is partially involved in type I IFN production in GM-DCs. This study provides important insight into the mechanisms of Ad vector-triggered innate immune responses, which may lead to more advanced and rational Ad vector designs for gene therapies and vaccine applications.

Efficient adenovirus vector-mediated PPAR gamma gene transfer into mouse embryoid bodies promotes adipocyte differentiation

Establishment of a transient gene delivery system, such as adenovirus (Ad) vectors, into embryonic stem (ES) cells and their aggregation form, embryoid bodies (EBs), is essential for its application in regenerative medicine because the transgene should not be integrated in the host genome. In this study, we optimized Ad vector‐mediated transduction into EBs, and examined whether Ad vector‐mediated transduction of adipogenesis‐related gene into EBs could promote the adipocyte differentiation.

Fiber-modified adenovirus vectors containing the TAT peptide derived from HIV-1 in the fiber knob have efficient gene transfer activity

The interaction between viral capsid proteins and specific molecules exposed on the plasma membrane of the cells is involved in the viral tropism. A human adenovirus (Ad) belonging to subgroups A, C, D, E and F infects cells via the interaction between the fiber knob and the primary receptor, the coxsackievirus and adenovirus receptor (CAR). Conventional human adenovirus type 5 (hAd5) vectors show efficient transduction in CAR-positive cells; in contrast, hAd5 vector application is limited by poor transduction into cells lacking CAR expression. In the present study, to broaden the tropism of hAd5 vectors, we generated hAd5 vectors containing the TAT peptide, which is a protein transduction domain derived from human immunodeficiency virus, in the HI loop of the fiber knob (Ad-TAT(HI)-L2) or the C-terminus of the fiber knob (Ad-TAT(C)-L2). In CAR-negative adherent cells, Ad-TAT(HI)-L2 and Ad-TAT(C)-L2 showed approximately 50- to 500-fold higher gene expression than the conventional hAd5 vector (Ad-L2). Ad-TAT(HI)-L2 was also more efficient than Ad-L2 in blood cell lines and in two types of primary cultured human vascular smooth muscle cells, which are almost refractory to Ad-L2. Furthermore, Ad-TAT(HI)-L2 was more efficient than other types of fiber-modified Ad vectors, which harbor an RGD (Arg-Gly-Asp) or a poly-lysine (KKKKKKK;K7) peptide in the HI loop or the C-terminus of the fiber knob, respectively. Ad-TAT(HI)-L2 efficiently transduced the organs in levels and patterns that were roughly similar to those of Ad-L2 after being systemically injected into mice. To the best of our knowledge, this study is the first report showing that hAd5 vectors containing the TAT peptide in the fiber knob could efficiently transduce cells independently of CAR. These Ad vectors should be useful for gene functional analysis and gene therapy.

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.

Development of fiber-substituted adenovirus vectors containing foreign peptides in the adenovirus serotype 35 fiber knob.

Fiber-substituted adenovirus (Ad) vectors containing fibers of Ad serotype 35 (AdF35) efficiently transduce a variety of human cells because their receptor, human CD46, is ubiquitously expressed on almost all nucleated cells. However, the ubiquitous expression of CD46 might lead to unexpected transduction in untargeted organs. In this study, we developed fiber-modified AdF35 vectors with an integrin-binding Arg-Gly-Asn (RGD) peptide incorporated into the FG, HI or IJ loop, which have been identified as important regions for binding to CD46. Incorporation of foreign peptides into these loops does not inhibit trimerization of the fibers. In CD46-negative cells, fiber-mutant AdF35 vectors containing an RGD peptide in the FG or HI loop showed 6- to 30-fold higher transduction efficiencies in an RGD-peptide-dependent manner than the unmodified AdF35 vectors. In contrast, in CD46-positive cells, insertion of foreign peptides markedly reduced the transduction efficiencies of the AdF35 vectors, indicating that insertion of foreign peptides significantly inhibits binding to CD46. In particular, CD46-mediated transduction was completely diminished by insertion of foreign peptides into the HI loop. Our findings indicate that HI loop is the most suitable domain to mediate a foreign peptide-dependent and CD46-independent transduction by incorporation of foreign peptides into the Ad35 fiber knob.

Enhanced transduction efficiency of fiber-substituted adenovirus vectors by the incorporation of RGD peptides in two distinct regions of the adenovirus serotype 35 fiber knob.

Fiber-substituted Ad serotype 5 vectors containing the fiber protein from Ad serotype 35 (Ad5F35) exhibit properties that render them suitable as a platform for targeted Ad vectors. Ad5F35 vectors do not show apparent tropism in certain organs, including the liver, and they elicit less innate immunity than other vectors after intravenous administration. In order to develop a targeted Ad vector, we previously developed fiber-mutant Ad5F35 vectors containing the integrin binding Arg-Gly-Asn (RGD) motif in the FG or HI loop of the Ad35 fiber knob. Mutant Ad5F35 vectors containing the RGD peptide in the FG or HI loop transduced CD46-negative cells more efficiently in an RGD-dependent manner, as compared to the efficiency achieved with unmodified Ad5F35 vectors (Matsui et al., 2009. Gene Therapy 16, 1050-1057). However, the transduction efficiency of the mutant Ad5F35 vectors in CD46-negative cells remained lower than had been expected. Ad5F35 vectors containing the RGD peptide in the HI or FG loop enabled a 6-fold higher transduction efficiency than that achieved with unmodified Ad5F35 vectors in CD46-negative cells, although this cell type abundantly expresses α(v)-integrins. In the present study, we aimed to enhance the transduction efficiency of fiber-mutant Ad5F35 vectors. To this end, we developed an Ad5F35-vector system in which foreign peptides could be incorporated into regions of FG and HI loops of the Ad35 fiber knob by means of in vitro ligation. Using this Ad5F35-vector system, firefly luciferase-expressing mutant Ad5F35 vectors containing the RGD peptides in both loops (Ad5F35-2xRGD-L2) were constructed. In CD46-negative cells, Ad5F35-2xRGD-L2 showed 12-fold and 3-fold greater transduction efficiency than unmodified Ad5F35 vectors and mutant Ad5F35 vectors containing only one copy of the RGD peptide in the FG or the HI loop. In addition, transduction with Ad5F35-2xRGD-L2 in CD46-negative cells was RGD peptide-dependent. These results indicate that fiber-mutant Ad5F35 vectors, by which foreign peptides can be simultaneously incorporated into both the FG and the HI loops of the Ad35 fiber knob, could be a promising gene delivery vehicle for various gene therapies, and could facilitate basic research efforts such as analyses of gene function.

Modification of pIX or hexon based on fiberless Ad vectors is not effective for targeted Ad vectors.

Adenovirus (Ad) vector application in gene therapy is limited by its naïve tropism. We previously developed protein IX (pIX)-modified and hexon-modified Ad vectors in order to alter Ad vector tropism. However, these modified Ad vectors failed to infect cells with the foreign ligands displayed in the pIX or hexon. We hypothesized that steric hindrance by fiber proteins might have prevented the ligand-mediated transduction, as fibers are the outmost capsid proteins of Ad vectors. Therefore, we generated a series of fiberless Ad vectors and investigated their gene expression properties. Unexpectively, however, pIX- or hexon-modified fiberless Ad vector did not achieve any gene expression (the gene expression level by these vectors was similar to the background level). These results might be caused by the fact that the fiberless particles were weaker against physical burdens. To the best of our knowledge, this study is the first reported attempt to develop fiberless Ad vectors containing foreign ligands in the pIX or hexon region. The drawback of the lower stability of fiberless Ad vectors must be overcome to develop targeted Ad vectors based on such vectors. This study could provide basic information for the development of effective targeted Ad vectors.

Synthesis of a RGD Peptide-PEG Hybrid for Carrying Adenovirus Vector into Cells

Shinya Kida, Mitsuko Maeda, Keiko Hojo, Yusuke Eto, Jian-Qing Gao, Shinnosuke Kurachi, Fumiko Sekiguchi, Hiroyuki Mizuguchi, Takao Hayakawa, Tadanori Mayumi, Shinsaku Nakagawa and Koichi Kawasaki Faculty of Pharmaceutical Sciences, Kobe Gakuin University, Nishi-ku, Kobe 651-2180, Japan; Graduate School of Pharmaceutical Sciences, Osaka University, Yamadaoka, Suita 565-0871, Japan; Division of Cellular and Gene Therapy Products, National Institute of Health Sciences, Setagaya-ku, Tokyo 158-8501, Japan; National Institute of Health Sciences, Setagaya-ku, Tokyo 158-8501, Japan