Adenoviruses have so far been through three generations of development. Some of the strategies for modification of adenoviruses are described below.
Attenuation For adenovirus replication to occur, the host cell must be induced into
S phase by viral proteins interfering with cell cycle proteins. The adenoviral E1A gene is responsible for inactivation of several proteins, including
retinoblastoma, allowing entry into S-phase. The adenovirus E1B55kDa gene cooperates with another adenoviral product, E4ORF6, to inactivate
p53, thus preventing
apoptosis. It was initially proposed that an adenovirus
mutant lacking the E1B55kDa gene,
dl1520 (ONYX-015), could replicate selectively in
p53 deficient cells. A conditionally replicative adenovirus (CRAd) with a 24
base pair deletion in the
retinoblastoma-binding domain of the E1A
protein (
Ad5- Δ24E3), is unable to silence retinoblastoma, and therefore unable to induce S-phase in host cells. This restricts
Ad5-Δ24E3 to replication only in proliferating cells, such as tumour cells.
Targeting The most commonly used group of adenoviruses is
serotype 5 (Ad5), whose binding to
host cells is initiated by interactions between the cellular
coxsackie virus and adenovirus receptor (CAR), and the knob domain of the adenovirus coat protein
trimer. CAR is necessary for adenovirus infection. Although expressed widely in
epithelial cells, CAR expression in tumours is extremely variable, leading to resistance to Ad5 infection. The use of adapter molecules has been shown to increase viral transduction. However, adapters add complexity to the system, and the effect of adapter molecule binding on the stability of the virus is uncertain. •
Coat-protein modification :This method involves genetically modifying the fiber knob domain of the viral coat protein to alter its specificity. Short
peptides added to the
C-terminal end of the coat protein successfully altered viral tropism. The addition of larger peptides to the C-terminus is not viable because it reduces adenovirus integrity, possibly due to an effect on fiber trimerisation. The fiber protein also contains an HI-loop structure, which can tolerate peptide insertions of up to 100 residues without any negative effects on adenovirus integrity. An RGD motif inserted into the HI loop of the fiber knob protein, shifts specificity toward
integrins, which are frequently over-expressed in
oesophageal adenocarcinoma. When combined with a form of non-transductional targeting, these viruses proved to be effective and selective therapeutic agents for Oesophageal Adenocarcinoma. •
Transcriptional targeting :This approach takes advantage of deregulated promoter to drive and control the expression of adenoviral genes. For instance,
Cyclooxygenase-2 enzyme (Cox-2) expression is elevated in a range of cancers, and has low liver expression, making it a suitable tumour-specific promoter.
AdCox2Lluc is a CRAd targeted against
oesophageal adenocarcinoma by placing the early genes under the control of a Cox-2 promoter (adenoviruses have two early genes, E1A and E1B, that are essential for replication). •
Post-Transcriptional detargeting :Another layer of regulation that has emerged to control adenoviral replication is the use of
microRNAs (miRNA) artificial target sites or miRNA response elements (MREs). Differential expression of miRNAs between healthy tissues and tumors permit to engineer oncolytic viruses in order to have their ability to replicate impaired in those tissues of interest while allowing its replication in the tumor cells.
Arming with Transgenes To enhance the efficacy, therapeutic transgenes are integrated into oncolytic adenovirus •
stimulation of immune response Immunostimulatory genes Like interferon α (IFNα), tumor necrosis factor alpha (TNFα), and
interleukin 12 (IL-12) have been integrated into oncolytic adenovirus to enhance immune response inside the
tumor microenvironment. When these molecules selectively expressed in tumor cells, oncolytic adenoviruses promote immune responses against tumor and minimize systemic side effects •
Enhancement of Ag presentation Oncolytic adenoviruses have been genetically modified with transgene encoding for granulocyte-macrophage
colony-stimulating factor (
GM-CSF) to enhance tumor antigens presentation by antigen-presenting cells (APCs). This approach aims to improve recognition of tumor by T-cell and subsequent immune responses, •
Targeting costimulatory and Immune Checkpoints on T-cells Oncolytic adenoviruses have been genetically engineered to express checkpoint inhibitors (CTLA-4, anti-PD-L1 antibodies) to release brake of T-cell activity, and to express costimulatory molecules (CD40L, 4-1BBL) to augment T-cell activation and proliferation, ==Examples==