Retroviruses Retroviruses—enveloped RNA viruses—are popular viral vector platforms due to their ability to integrate genetic material into the host genome. Retroviral vectors comprise two general classes: gamma retroviral and lentiviral vectors. The fundamental difference between the two are that gamma retroviral vectors can only infect dividing cells, while lentiviral vectors can infect both dividing and resting cells. Notably, retroviral genomes are composed of single-stranded RNA and must be converted to proviral double-stranded DNA, a process known as
reverse transcription—before it is integrated into the host genome via viral proteins like
integrase. The most commonly used gammaretroviral vector is a modified
Moloney murine leukemia virus (MMLV), able to transduce various mammalian cell types. MMLV vectors have been associated with some cases of carcinogenesis. Gammaretroviral vectors have been successfully applied to
ex vivo hematopoietic stem cell to treat multiple genetic diseases.
Lentiviral vectors Most lentiviral vectors are derived from
human immunodeficiency virus type 1 (HIV-1), although modified
simian immunodeficiency virus (SIV), the
feline immunodeficiency virus (FIV), and the
equine infectious anaemia virus (EIAV) have also been utilized. As all functional genes are removed or otherwise mutated, the vectors are not
cytopathic and can be engineered to be non-integrative. Lentiviral vectors are able to carry up to 10 kb of foreign genetic material, although 3-4 kb was reported as optimal as of 2023. Relative to other viral vectors, lentiviral vectors possess the greatest transduction capacity, due to the formation of a three-stranded "DNA flap" during retro-transcription of the single-strand lentiviral RNA to DNA within the host. Although largely non-inflammatory, lentiviral vectors can induce robust adaptive immune responses by memory-type
cytotoxic T cells and
T helper cells. This is largely due to lentiviral vectors' high tropism for
dendritic cells, which activate T cells. However, they can infect all types of antigen-presenting cells. Moreover, as they are the only retroviral vectors able to efficiently transduce both dividing and non-dividing cells, make them the most promising vaccine platforms. They have also been trialed as vaccines against cancer. Lentiviral vectors have been used as
in vivo therapies, such as directly treating genetic diseases like
haemophilia B and for
ex vivo treatments like immune cell modification in
CAR T cell therapy. In 2017, the
US Food and Drug Administration (FDA) approved
tisagenlecleucel, a lentiviral vector, for
acute lymphoblastic leukaemia.
Adenoviruses (visualized via electron micrograph at left and right and depicted graphically at center) are commonly used as viral vector platforms. Note the
icosahedron capsid structure. Adenoviruses are double-stranded DNA viruses belonging to the family
Adenoviridae. Their relatively large genomes, of approximately 30–45 kb, make them ideal candidates for genetic delivery; newer adenoviral vectors can carry up to 37 kb of foreign genetic material. Adenoviral vectors display high transduction efficiency and transgene expression, and can infect both dividing and non-dividing cells. The adenoviral capsid, an
icosahedron, features a fibre "knob" at each of its 12 vertices. These fibre proteins mediate cell entry—greatly affecting efficacy and contribute to its broad tropism—notably via
coxsackie–adenovirus receptors (CARs). Adenoviral vectors can induce robust innate and adaptive immune responses. Its strong immunogenicity is particularly due to the transduction of dendritic cells (DC), upregulating the expression of both MHC I and II molecules and activating the DCs. They have a strong adjuvant effect, as they display several
pathogen-associated molecular patterns. One disadvantage is that pre-existing immunity to adenovirus serotypes is common, reducing efficacy. The use of chimpanzee adenoviruses may circumvent this issue. While the activation of both innate and adaptive immune responses is an obstacle for many therapeutic applications, it makes adenenoviral vectors an ideal vaccine platform. The global response to the COVID-19 pandemic saw the development and use of multiple adenoviral vector vaccines, including
Sputnik V, the
Oxford–AstraZeneca vaccine, and the
Janssen vaccine.
Adeno-associated viruses Adeno-associated viruses (AAVs) are relatively small single-stranded DNA viruses belonging to
Parvoviridae and, like lentiviral vectors, AAVs can infect both dividing and non-dividing cells. AAVs, however, require the presence of a "helper virus" such as an adenovirus or herpes simplex virus to replicate within the host, although it can do so independently if
cellular stress is induced or the helper virus genes are carried by the vector. AAVs insert themselves into a specific site in the host genome, particularly
AAVS1 on
chromosome 19 in humans. However, recombinant AAVs have been designed that do not integrate. These are instead stored as episomes that, in non-dividing cells, can last for years. One disadvantage is that they are not able to carry large amounts of foreign genetic materials. Furthermore, the need to express the complementary strand for its single-stranded genome may delay transgene expression. As of 2020, 11 different AAV serotypes—differing by capsid structure and consequently by tropism—had been identified. The tropism of adeno-associated viral vectors can be tailored by creating recombinant versions from multiple serotypes, termed pseudotyping. Due to their ability to infect and induce longlasting effects within nondividing cells, AAVs are commonly used in basic neuroscience research. Following the approval of the AAV
Alipogene tiparvovec in Europe in 2012, in 2017, the FDA approved the first AAV-based in vivo gene therapy—
voretigene neparvovec—which treated
RPE65-associated Leber congenital amaurosis. As of 2020, 230 clinical trials using AAV-based treatments were either underway or had been completed.
Vaccinia Vaccinia virus, a
poxvirus, is another promising candidate for viral vector development. Its use as the
smallpox vaccine—first reported by
Edward Jenner in 1798—led to the eradication of
smallpox and demonstrated vaccinia as safe and effective in humans. Moreover, manufacturing procedures developed to mass-produce smallpox vaccine stockpiles may expedite vaccinia viral vector production. Vaccinia possesses a large DNA genome and can consequently carry up to 40 kb of foreign DNA. Further, vaccinia are unlikely to integrate into the host genome, decreasing the chance of carcinogenesis. Attenuated strains—replicating and non-replicating—have been developed. Although widely characterized due to its use against smallpox, as of 2019 the function of 50 percent of the vaccinia genome was unknown. This may lead to unpredictable effects. As a vaccine platform, vaccinia vectors display highly effective transgene expression and create a robust immune response. The virus fast-acting: its life cycle produces mature progeny vaccinia within 6 hours, and has three viral spread mechanisms. Vaccinia also has an
adjuvant effect, activating a strong
innate response via
toll-like receptors. A significant disadvantage that can reduce its efficacy, however, is pre-existing immunity against vaccinia in those who received the smallpox vaccine.
Herpesviruses Of the nine
herpesviruses that infect humans, herpes simplex virus 1 (HSV-1) is the most well characterized and most commonly used as a viral vector. HSV-1 offers several advantages: it has broad tropism and can deliver therapeutics via specialized expression systems. Moreover, HSV-1 can cross the blood brain barrier if medically-disrupted, enabling it to target neurological diseases. Also, HSV-1 does not integrate into the host genome and can carry large amounts of foreign DNA. The former feature prevents harmful mutagenesis, as can occur with retroviral and adeno-associated vectors. Replication-deficient strains have been developed. In 2015,
talimogene laherparepvec—an HSV-1 vector that triggers an anti-tumor immune response—was approved by the FDA to treat
melanoma. As of 2020, HSV-1 vectors have been experimentally applied against
sarcomas and cancers of the brain, colon, prostate, and skin.
Cytomegalovirus (CMV), a herpesvirus, has also been developed for use as a viral vector. CMV can infect most cell types and can thus proliferate throughout the body. Although a CMV-based vaccine provided significant immunity against SIV—closely related to HIV—in macaques, development of CMV as a reliable vector was reported to still be in early stages as of 2020.
Plant viruses Plant viruses are also engineered viral vectors for use in agriculture, horticulture, and
biologic production. These vectors have been employed for a range of applications, from increasing the aesthetic quality of
ornamental plants to
pest biocontrol, rapid expression of recombinant proteins and peptides, and to accelerate crop breeding. The use of engineered plant viruses has been proposed to enhance crop performance and promote sustainable production. Replicating virus-based vectors are typically used. RNA viruses used for monocots include
wheat streak mosaic virus and
barley stripe mosaic virus and, for dicots,
tobacco rattle virus. Single-stranded DNA viruses like
geminiviruses have also been utilized. Viral vectors can be administered to plants via several pathways termed "agro-inoculation", including via rubbing, a
biolistic delivery system, agrospray, agroinjection, and even via
insect vectors. However,
Agrobacterium-mediated delivery of viral vectors—in which bacteria are transformed with
plasmid DNA encoding the viral vector construct—is the most common approach.
Bacteriophages Chimeric vectors combining both bacteriophages and eukaryotic viruses have been developed and are capable of infecting eukaryotic cells. Unlike eukaryotic virus-based vectors, such bacteriophage vectors have no innate tropism for eukaryotic cells, allowing them to be engineered to be highly specific for cancer cells. Bacteriophage vectors are also commonly used in molecular biology. For instance, bacteriophage vectors are used in
phage-assisted continuous evolution, promoting rapid mutagenesis of bacteria. Although limited to
mycobacteriophages and some phages of
gram-negative bacteria, bacteriophages can be used for direct cloning. ==Manufacture==