Human species C adenovirus serotype 5 (Ad5) is the most common viral vector used in clinical studies worldwide. Ad5 vectors infect liver cells in vivo with high efficiency via a poorly defined mechanism, which involves virus binding to vitamin K-dependent blood coagulation factors. Here, we report that the major Ad5 capsid protein, hexon, binds human coagulation factor X (FX) with an affinity of 229 pM. This affinity is 40-fold stronger than the reported affinity of Ad5 fiber for the cellular receptor coxsackievirus and adenovirus receptor, CAR. Cryoelectron microscopy and single-particle image reconstruction revealed that the FX attachment site is localized to the central depression at the top of the hexon trimer. Hexon-mutated virus bearing a large insertion in hexon showed markedly reduced FX binding in vitro and failed to deliver a transgene to hepatocytes in vivo. This study describes the mechanism of FX binding to Ad5 and demonstrates the critical role of hexon for virus infection of hepatocytes in vivo.gene transfer ͉ virus targeting
Virotherapy is currently undergoing a renaissance, based on our improved understanding of virus biology and genetics and our better knowledge of many different types of cancer. Viruses can be reprogrammed into oncolytic vectors by combining three types of modification: targeting, arming and shielding. Targeting introduces multiple layers of cancer specificity and improves safety and efficacy; arming occurs through the expression of prodrug convertases and cytokines; and coating with polymers and the sequential usage of different envelopes or capsids provides shielding from the host immune response. Virus-based therapeutics are beginning to find their place in cancer clinical practice, in combination with chemotherapy and radiation.
DNA is the accepted target for cisplatin, but recent evidence has shed doubt on DNA synthesis as the critical process. L1210/0 cells incubated for 2 hours with cisplatin progress to the G2 phase of the cell cycle and are arrested there for several days. They then either progress in the cell cycle or die. In cells that eventually die, total transcription, polyadenylated [poly(A)+] RNA synthesis, and protein synthesis were markedly inhibited only after 48 hours. Nicotinamide adenine dinucleotide (NAD) and adenosine triphosphate (ATP) levels decreased after 3 days. Cell membrane integrity was lost after 4 days. These results demonstrate that cells can be lethally damaged, yet continue to undergo apparently normal metabolic activities for several days. In a previous study, DNA double-strand breaks were detected after 1 day. We now show that by 2 days, breaks are visible as fragmentation in the nucleosome spacer regions of chromatin. This type of damage is consistent with cell death occurring by the process of apoptosis. Cell shrinkage and morphology were also consistent with this type of cell death. The slow cell death reported here appears to occur at the G2/M transition and may involve events that normally occur at this stage of the cell cycle. These results demonstrate the importance of DNA degradation as an early and possibly essential step in cell death.
Adenoviruses are robust gene delivery vectors in vivo, but are limited by their propensity to provoke strong innate and adaptive responses. Previous work has demonstrated that polyethylene glycol (PEG) modification of adenovirus can protect the vectors from preexisting and adaptive immune responses by reducing protein-protein interactions. To test whether PEGylation can reduce innate immune responses to adenovirus by reducing their interactions with immune cells, first-generation (FG-Ad) and helper-dependent (HD-Ad) Ad5 vectors were PEGylated with SPA-PEG and tested in vitro and in vivo. We demonstrate that increasing PEGylation ablated in vitro transduction, but surprisingly had no negative effect on the level or distribution of in vivo gene delivery. This poor in vitro transduction could be rescued in part by physically forcing the PEGylated vectors onto cells, suggesting that physiological forces in vivo may enable transduction via heparin sulfate proteoglycan and integrin interactions. While transduction remained the same as for unmodified vectors, the PEGylated vectors reduced innate IL-6 responses by 70 and 50% in vivo for FG-Ad and HD-Ad. These reduced innate responses paralleled similar reductions in vector uptake by macrophages in vitro and Kupffer cells in vivo. These data suggest that PEGylation of Ad vectors can reduce innate immune responses without reducing transduction in vivo. These data also suggest that nonspecific vector uptake by macrophages and Kupffer cells may be critically involved in the initial activation of innate immune responses.
More than two decades have passed since genetically modified HIV was used for gene delivery. Through continuous improvements these early marker gene-carrying HIVs have evolved into safer and more effective lentiviral vectors. Lentiviral vectors offer several attractive properties as gene-delivery vehicles, including: (i) sustained gene delivery through stable vector integration into host genome; (ii) the capability of infecting both dividing and non-dividing cells; (iii) broad tissue tropisms, including important gene- and cell-therapy-target cell types; (iv) no expression of viral proteins after vector transduction; (v) the ability to deliver complex genetic elements, such as polycistronic or intron-containing sequences; (vi) potentially safer integration site profile; and (vii) a relatively easy system for vector manipulation and production. Accordingly, lentivector technologies now have widespread use in basic biology and translational studies for stable transgene overexpression, persistent gene silencing, immunization, in vivo imaging, generating transgenic animals, induction of pluripotent cells, stem cell modification and lineage tracking, or site-directed gene editing. Moreover, in the present high-throughput ‘-omics’ era, the commercial availability of premade lentiviral vectors, which are engineered to express or silence genome-wide genes, accelerates the rapid expansion of this vector technology. In the present review, we assess the advances in lentiviral vector technology, including basic lentivirology, vector designs for improved efficiency and biosafety, protocols for vector production and infection, targeted gene delivery, advanced lentiviral applications and issues associated with the vector system.
Ideal gene therapy vectors would be delivered intravenously to transfect only specific cells. Existing vectors only transfect cells in vivo in a manner determined by blood flow and the site of introduction. As a general and systematic approach for generating cell-targeting ligands for gene therapy vectors, we have used peptide-presenting phage libraries to select peptides that bind and enter several different cell types. Because of their small size, cell-binding peptides such as these could be incorporated into biological or physical gene therapy vectors. In addition, peptide-presenting phage themselves may also be candidates for gene therapy vectors.
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