Activation and Role of Memory CD8 T Cells in Heterologous Antiviral Immunity and Immunopathology in the Lung: A Dissertation

Chen, Hong

09 December 2002

Each individual experiences many sequential infections throughout the lifetime. An increasing body of work indicates that prior exposure to unrelated pathogens can greatly alter the disease course during a later infection. This can be a consequence of a phenomenon known as heterologous immunity. Most viruses invade the host through the mucosa of a variety of organs and tissues. Using the intranasal mucosal route of infection, the thesis focused on studying modulation of lymphocytic choriomeningitis virus (LCMV)-specific memory CD8 T cells upon respiratory vaccinia virus (VV) infection and the role of these memory CD8 T cells in heterologous immunity against VV and altered immunopathology in the lung. The VV infection had a profound impact on memory T cells specific for LCMV. The impact included the up-regulation of CD69 expression on LCMV-specific CD8 memory T cells and the activation of their in vivoIFN-γ production and cytotoxic function. Some of these antigen-specific memory T cells selectively expanded in number, resulting in modulation of the original LCMV-specific T cell repertoire. In addition, there was a selective organ-dependent redistribution of these LCMV-specific memory T cell populations in secondary lymphoid tissue (the mediastinal lymph node and spleen) and the non-lymphoid peripheral (the lung) organs. The presence of these LCMV-specific memory T cells correlated with IFN-γ-dependent enhanced VV clearance, decreased mortality and marked changes in lung immunopathology. Thus, the participation of pre-existing memory T cells specific for unrelated agents can alter the dynamics of mucosal immunity. This is associated with an altered disease course in response to a pathogen. The roles for T cell cross-reactivity and cytokines in the modulation of memory CD8 T cells during heterologous memory CD8 T cell-mediated immunity and immunopathology were investigated. Upon VV challenge, there were preferential expansions of several LCMV-specific memory CD8 T cell populations. This selectivity suggested that cross-reactive responses played a role in this expansion. Moreover, a VV peptide, partially homologous to LCMV NP 205, stimulated LCMV-NP205 specific CD8 T cells, suggesting that NP205 may be a cross-reactive epitope. Poly I:C treatment of LCMV-immune mice resulted in a transient increase but no repertoire alteration of LCMV-epitope-specific CD8 T cells. These T cells did not produce IFN-γ in vivo. These results imply that poly I:C, presumably through its induced cytokines, was assisting in initial recruitment of LCMV-specific memory CD8 T cells in a nonspecific manner. VV challenge of LCMV-immune IL-12KO mice resulted in activation and slightly decreased accumulation of LCMV-specific CD8 T cells. Moreover, there was a dramatic reduction of in vivoIFN-γ production by LCMV-specific IL-12KO CD8 T cells in the lung. I interpreted this to mean that IL-12 was important to augment IFN-γ production by memory CD8 T cells upon TCR engagement by antigens and to induce further accumulation of activated memory CD8 T cells during the heterologous viral infection. This thesis also systematically examined what effect the sequence of two heterologous virus challenges had on viral clearance, early cytokine profiles and immunopathology in the lung after infecting mice immune to one virus with another unrelated viruses. Four unrelated viruses, [LCMV, VV, influenza A virus or murine cytomegalovirus (MCMV)], were used. There were many common changes observed in the acute response to VV as a consequence of prior immunity to any of three viruses, LCMV, MCMV or influenza A virus. These included the enhanced clearance of VV in the lung, associated with enhanced TH1 type responses with increased IFN-γ and suppressed pro-inflammatory responses. However, immunity to the three different viruses resulted in unique pathologies in the VV-infected lungs, but with one common feature, the substitution of lymphocytic and chronic mononuclear infiltrates for the usual acute polymorphonuclear response seen in non-immune mice. Immunity to influenza A virus appeared to influence the outcome of subsequent acute infections with any of the three viruses, VV, LCMV and MCMV. Most notably, influenza A virus-immunity protected against VV but it actually enhanced LCMV and MCMV titers. This enhanced MCMV replication was associated with enhanced TH1 type response and pro-inflammatory cytokine responses. Immunity to influenza A virus appeared to dramatically enhance the mild lymphocytic and chronic mononuclear response usually observed during acute infection with either LCMV or MCMV in non-immune mice, but LCMV infection and MCM infection of influenza A virus-immune mice each had its own unique features. Thus, the specific sequence of virus infections controls the outcome of disease.

Immunologic Memory

Immunity

Mucosal

Vaccinia virus

Antigens

CD8

CD8-Positive T-Lymphocytes

Lymphocytic choriomeningitis virus

Animal Experimentation and Research

Biological Factors

Cells

Hemic and Immune Systems

Viruses

Fragment-screening by X-ray crystallography of human vaccinia related kinase 1

Ali Rashid Majid, Yousif

January 2020

Fragment-screening by X-ray crystallography (XFS) is an expensive and low throughput fragment drug discovery screening method, and it requires a lot of optimization for each protein target. The advantages with this screening method are that it is very sensitive, it directly gives the three-dimensional structure of the protein-fragment complexes, and false positives are rarely obtained. The aim of this project was to help Sprint Bioscience assess if the advantages with XFS outweigh the disadvantages, and if this method should be used as a complement to their differential scanning fluorimetry (DSF) screening method. An XFS campaign was run using the oncoprotein vaccinia related kinase 1 (VRK1) as a target protein to evaluate this screening method. During the development of the XFS campaign, a diverse fragment library was created which consisted of 298 fragments that were all soluble in DMSO at 1 M concentration. The crystallization of the protein VRK1 was also optimized in this project to get a robust, high throughput crystallization set up which generated crystals that diffracted at higher resolution than 2.0 Å when they were not soaked with fragments. The soaking protocol was also optimized in order to reduce both the steps during the screening procedure and mechanical stress caused to the crystals during handling. Lastly, the created fragment library was used in screening VRK1 at 87.5 mM concentration with XFS. 23 fragment hits could be obtained from the X-ray crystallography screening campaign, and the mean resolution of the crystal structures of the protein-fragment complexes was 1.87Å. 11 of the 23 fragment hits were not identified as hits when they were screened against VRK1 using DSF. XFS was deemed as a suitable and efficient screening method to complement DSF since the hit rate was high and fragments hits could be obtained with this method that could not be obtained with DSF. However, in order to use this screening method a lot of time needs to be spent in optimizing the crystal system so it becomes suitable for fragment screening. Sprint Bioscience would therefore need to evaluate the cost/benefit ratio of using this screening method for each new project.

Fragment based drug discovery

X-ray crystallography

screening

vaccinia related kinase 1

crystal optimization

fragment library design

differential scanning fluorimetry

Sprint Bioscience

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Immunity, Pathogenesis, and Prevention of Poxvirus Infections: A Dissertation

Seedhom, Mina O.

15 December 2010

Vaccinia virus (VAC) is the prototypical member of the orthopoxvirus genus of the poxvirus family and the virus used for smallpox vaccinations. The following describes the testing of VAC variants designed to have similar immuno-protective profiles with decreased pathogenicity, examines the immune response to VAC after lethal infection in wild type and lupus-prone mice, and describes a method that allows for the enumeration of VAC-specific CD8+ T in naïve and VAC-immune mice. The first part describes work examining VAC Wyeth (VAC-Wy) variants engineered to be less pathogenic in vivo. VAC-Wy variants included genes that code for three immunomodulatory proteins, an interferon-γ (IFNγ) binding protein (B8R), an interleukin 18 (IL-18) binding protein (C12L), and a complement binding protein (C3L, or C21L) or various combinations of the three knockouts, and a triple knockout (VAC-Wy -/-/-) in which all three genes were knocked out of a variant virus. The immunomodulatory effects of other IFNγ binding proteins on VAC-Wy pathogenesis in the mouse were also examined. Virus recombinants where the B8R gene was replaced with a truncated mouse IFNγ receptor gene or a gene that encodes a B8R/IFNγ fusion that allows for dimerization of the secreted IFNγ receptor were studied. As the knockouts and variants were made in the current vaccine VAC-Wy strain, only high dose (1x107 PFU’s) intra nasal (I.N.) infection of mice reliably resulted in detectable virus in the lungs. Further testing revealed that all knockout and variant viruses grew to similar levels after high dose I.N. infections. Protection induced by vaccination with the VAC-Wy variants was studied in comparison to immunizations with the VAC-Wy parental strain. Mice were immunized by tail skin scarification to mimic human immunizations, and this was followed months later by I.N. challenge with 20 LD50’s of VAC-WR. All VAC-Wy recombinants tested, including the VAC-Wy -/-/-, provided similar levels of protection as the parental VAC-Wy strain from a lethal VAC-WR I.N. infection. Mice immunized with the VAC-Wy -/-/- induced similar amounts of neutralizing antibody and similar numbers of CD8+ T cells specific to a subdominant determinant as VAC-Wy. While examining high dose, normally lethal, VAC-WR I.N. infections, a profound splenic CD8+ T cell immune suppression was noted that might have been caused by Fas dependent activation induced cell death (AICD). Using high dose intra-peritoneal (I.P.) and I.N. models of VAC-WR infection, decreased weight loss, decreased virus titers, and increased T cell numbers were found in Fas mutant (B6.MRL-Faslpr/J) mice in comparison to B6 wild type mice on day 6. It would be expected that Fas-deficient CD8+ T cells from B6.MRL-Faslpr/J mice (B6-lpr) would survive a high dose VAC-WR infection better than CD8+ T cells that could express Fas if T cells were being eliminated by Fas-dependent AICD, but co-adoptive transfer experiments using splenocytes from B6-lpr and B6.Cg- IgHaThy-1aGPi-1a/J (IgHa) wild type counterparts found no difference in the numbers or proliferation of donor CD8+ T cells at day 6. As the B6-lpr mice were better protected from VAC-induced weight loss early after lethal VAC-WR infections, it was possible that B6-lpr mice might be protected early in infection. In fact, Fas mutant mice had decreased virus loads in the fat pads, livers, and spleens in comparison to B6 wild type mice at days 2 and 3. In addition to the decreased virus titers, the severe splenic lymphocyte deficiency noted in B6 wild type mice as early as day 2 after high dose I.P. infection was ameliorated in B6-lpr mice. Further experiments demonstrated that uninfected B6-lpr mice had increased numbers of memory phenotype (CD44+) CD4+, CD8+ and γδ+ T cells, with an increased number of γδ+ T cells and NK cells in splenic lymphocytes in comparison to wild type B6 mice. Uninfected B6-lpr mice also had increased numbers of IFNγ+ CD8+ T cells after polyclonal stimulation with an antibody against CD3ε. In lymphocyte depletion experiments performed at day 3, antibody depletion of CD4, CD8, or NK or treatment with an antibody that was specific to the γδ+ TCR did not significantly alter virus loads in B6-lpr mice. In co-adoptive transfer experiments, splenocytes from wild type or B6-lpr mice survived high dose VAC-WR challenge similarly suggesting that B6- lpr splenocytes were not intrinsically better protected from lymphocyte depletion by lack of the Fas protein. On day 2 after high dose I.P. VAC-WR infection, B6- lpr mice had increased numbers of IFNγ+ NK cells, IFNγ+ CD8+ T cells, and IFNγ+ CD4+ T cells. B6-lpr and B6 mice treated with an antibody against IFNγ had significantly increased virus titers in the spleens and livers. Interestingly, there was no significant difference in liver or spleen virus titers when comparing anti- IFNγ antibody treated B6 mice or anti-IFNγ antibody treated B6-lpr mice. These results suggest that multiple leukocyte populations co-operatively or redundantly provide B6-lpr mice with increased protection from high dose VAC-WR infections through increased production of IFNγ. The third part of this work describes the enumeration of total numbers of pathogen-specific CD8+ T cells in a mouse through use of an in vivo limiting dilution assay (LDA). The extensive proliferation of virus-specific CD8+ T cells that occurs after virus infection was used to enumerate numbers of virus-specific CD8+ T cells in a naïve mouse. By transferring limiting amounts of carboxyfluorescein succinimidyl ester (CFSE)-labeled Thy1.1+Ly5.2+ heterogeneous CD8+ T cells into Thy1.2+Ly5.1+ hosts, CD8+ T cell precursor frequencies to whole viruses can be calculated. The calculations are based on finding the number of donor CD8+ T cells that results in CFSElo (i.e. proliferated) donor CD8 T cells in 50% of the hosts. Using probit or Reed and Muench 50% endpoint calculations, CD8+ T cell precursor determinations were made for naïve and immune states to a virus challenge. It was found that in naïve B6 mice, 1 in 1444 CD8+ T cells proliferated in response to VAC-WR (~13,852 VAC-WR-specific CD8+ T cells per mouse) and 1 in 2956 proliferated in response to lymphocytic choriomeningitis virus (LCMV) (~6,761 LCMV-specific CD8+ T cells per mouse). In mice immune to VAC-WR, the number of VAC-WR-specific LDA precursors, not surprisingly, dramatically increased to 1 in 13 (~1,538,462 VAC-WR- specific CD8+ T cells per mouse) consistent with estimates of VAC-WR-specific memory T cells. In contrast, precursor numbers to LCMV did not increase in VAC-WR-immune mice (1 in 4562, ~4384 LCMV-specific CD8+ T cells in a VAC-WR-immune mouse) consistent with the fact that VAC-WR provides no heterologous immunity to LCMV. Using H-2Db-restricted LCMV GP33-specific P14 transgenic T cells it was found that, after accounting for take of donor T cells, approximately every T cell transferred underwent a full proliferative expansion in response to an LCMV infection and a high efficiency was also seen in memory populations. This suggests that most antigen-specific T cells will proliferate in response to infections at limiting dilution. These results, which are discussed in comparison to other methods, show that naïve and memory CD8+ T cell precursor frequencies to whole viruses can be remarkably high. In total this work further advances knowledge of the immunity, pathogenesis, and prevention of poxvirus infections. This was accomplished by studying VAC-Wy recombinants as improved vaccines, by examining the mechanisms and cell types important in early protection from high dose poxvirus infections in B6 and B6-lpr mice, and by describing a method to enumerate total numbers of virus-specific CD8+ T cells in a mouse.

Vaccinia virus

Poxviridae Infections

Immunity

Virulence

Animal Experimentation and Research

Environmental Public Health

Hemic and Immune Systems

Immunology and Infectious Disease

Investigative Techniques

Therapeutics

Virus Diseases

Viruses

Studies of HLA-DM in Antigen Presentation and CD4+ T Cell Epitope Selection: A Dissertation

Yin, Liusong

09 April 2014

Antigen presented to CD4+ T cells by major histocompatibility complex class II molecules (MHCII) plays a key role in adaptive immunity. Antigen presentation is initiated by the proteolytic cleavage of pathogenic or self proteins and loading of resultant peptides to MHCII. The loading and exchange of peptides to MHCII is catalyzed by a nonclassical MHCII molecule, HLA-DM (DM). It is well established that DM promotes peptide exchange in vitro and in vivo. However, the mechanism of DM-catalyzed peptide association and dissociation, and how this would affect epitope selection in human responses to infectious disease remain unclear. The work presented in this thesis was directed towards the understanding of mechanism of DM-mediated peptide exchange and its role in epitope selection. In Chapter II, I measured the binding affinity, intrinsic dissociation half-life and DM-mediated dissociation half-life for a large set of peptides derived from vaccinia virus and compared these properties to the peptide-specific CD4+ T cell responses. These data indicated that DM shapes the peptide repertoire during epitope selection by favoring the presentation of peptides with greater DM-mediated kinetic stability, and DM-susceptibility is a strong and independent factor governing peptide immunogenicity. In Chapter III, I computationally simulated peptide binding competition reactions and found that DM influences the IC50 (50% inhibition concentration) of peptides based on their susceptibility to DM, which was confirmed by experimental data. Therefore, I developed a novel fluorescence polarization-based method to measure DM-susceptibility, reported as a IC50 (change in IC50 in the absence and presence of DM). Traditional assays to measure DM-susceptibility based on differential peptide dissociation rates are cumbersome because each test peptide has to be individually labeled and multiple time point samples have to be collected. However, in this method developed here only single probe peptide has to be labeled and only single reading have to be done, which allows for fast and high throughput measure of DM-susceptibility for a large set of peptides. In Chapter IV, we generated a series of peptide and MHCII mutants, and investigated their interactions with DM. We found that peptides with non-optimal P1 pocket residues exhibit low MHCII affinity, low kinetic stability and high DM-susceptibility. These changes were accompanied with conformational alterations detected by surface plasmon resonance, gel filtration, dynamic light scattering, small-angle X-ray light scattering, antibody-binding, and nuclear magnetic resonance assays. Surprisingly, all these kinetic and conformational changes could be reversed by reconstitution with a more optimal P9 pocket residue. Taken together, our data demonstrated that conformation of MHCII-peptide complex constrained by interactions throughout the peptide binding groove is a key determinant of DM-susceptibility. B cells recognizing cognate antigen on the virion can internalize and process the whole virion for antigen presentation to CD4+ T cells specific for an epitope from any of the virion proteins. In turn, the epitope-specific CD4+ T cells provide intermolecular (also known as noncognate or heterotypic) help to B cells to generate antibody responses against any protein from the whole virion. This viral intermolecular help model in which CD4+ T cells provide help to B cells with different protein specificities was established in small size influenza virus, hepatitis B virus and viral particle systems. For large and complex pathogens such as vaccinia virus and bacteria, the CD4+ T cell-B cell interaction model may be complicated because B cells might not be able to internalize the large whole pathogen. Recently, a study in mice observed that CD4+ T cell help is preferentially provided to B cells with the same protein specificity to generate antibody responses against vaccinia virus. However, for larger pathogens such as vaccinia virus and bacteria the CD4+ T cell-B cell interaction model has yet to be tested in humans. In Chapter V, I measured in 90 recently vaccinated and 7 long-term vaccinia-immunized human donors the CD4+ T cell responses and antibody responses against four vaccinia viral proteins (A27L, A33R, B5R and L1R) known to be strongly targeted by cellular and humoral responses. We found that there is no direct linkage between antibody and CD4+ T cell responses against each protein. However, the presence of immune responses against these four proteins is linked together within donors. Taken together, our data indicated that individual viral proteins are not the primary recognition unit and CD4+ T cells provide intermolecular help to B cells to generate robust antibody responses against large and complicated vaccinia virus in humans.

Histocompatibility Antigens Class II

Antigen Presentation

T-Lymphocyte Epitopes

CD4-Positive T-Lymphocytes

B-Lymphocytes

Vaccinia virus

Dissertations, UMMS

Epitopes, T-Lymphocyte

Immunity

Immunology of Infectious Disease

Virology

TARGETING DNA DAMAGE AND REPAIR TO OVERCOME THERAPY MEDIATED TUMOR IMMUNE EVASION AND HETEROGENEITY IN THE CONTEXT OF ONCOLYTIC VIRUS VACCINATION

Kesavan, Sreedevi

January 2021

Due to the inevitable reality that most patients diagnosed with cancer will eventually relapse, modern oncology research has been forced to tackle this outcome primitively using combination therapies. Adoptive T-cell transfer with Oncolytic Virus Vaccination represents a new class of combination therapies that can facilitate the crosstalk of multiple aspects of the immune system such that they work in concert to prevent this outcome for many types of cancer. Despite this, immunosuppressive systems like those characterized in the B16F10-gp33 melanoma model pose a new problem for this approach. Typically, this model has total regression but is subsequently followed by relapse. Previous work from the Wan lab has suggested that this may be an outcome of total target gene deletion. Here we present two approaches to tackle this through the targeting of DNA repair pathways of the host cell. Our data can show that both VSV and Vaccinia infection/ propagation does lead to the generation of DNA damage but in the case of VSV this leads to incomplete cell lysis, and ultimately target gene loss via double-stranded DNA repair mechanisms. We were able to tackle the phenomenon following VSV administration by adding DNA repair inhibitors to the mix and showed that the proportion of cells that escaped after the loss of the target antigen was decreased by half when compared to the standard procedures. Additionally, this work also gave a preliminary understanding of how Vaccinia may achieve a similar outcome to this via its unique cytoplasmic replication mechanisms. / Thesis / Master of Science (MSc)

VSV

Vaccinia

DNA Damage

DNA Repair

ACT

OV

Combination Therapy

Oncolytic Virus Vaccines

Mirin

AZD7648

B16F10

Vesicular Stomatitis Virus

Melanoma

DNA Repair Inhibition

Structural and Biochemical Studies of Protein-Ligand Interactions: Insights for Drug Development

Mishra, Vidhi

January 2013

No description available.

Chemistry

Structural studies

biochemical studies

protein-ligand interactions

drug development

Helicobacter pylori

MTAN

SAH

vaccinia virus

Mycobacterium tuberculosis

folate biosynthetic pathway

The Development of Silver Nanoparticles as Antiviral Agents

Trefry, John Christopher

10 June 2011

No description available.

Nanoscience

Nanotechnology

Virology

silver

nanoparticle

vaccinia

virus

nanotechnology

antiviral

entry

broad-spectrum

virucidal

cytoprotective

macropinocytosis

HIV-1

vector

high-throughput

cytotoxicity

The Combination of Carboxylesterase-Expressing Oncolytic Vaccinia Virus and Irinotecan

Becker, Michelle Caitlin

14 January 2013

This project combines oncolytic Vaccinia virus (VV) with irinotecan (CPT-11) for the treatment of cancer. VV can infect, replicate in and destroy cancer cells, yet leave healthy cells relatively unaffected. CPT-11 is a chemotherapeutic of which ~5% is converted to the more active chemotherapeutic SN-38 by endogenous carboxylesterase (CE) enzymes. SN-38 is a topoisomerase I inhibitor that induces DNA double strand breaks, leading to growth arrest and apoptosis. Consequently, VV has been engineered to express a more effective isoform of the CE enzyme. The virus’ tumour tropism should restrict enhanced conversion of CPT-11 to the tumour. Neither CPT-11 nor SN-38 interfered with VV replication or spread. Engineered recombinants expressed CE enzyme which, when combined with CPT-11, produced DNA double strand breaks and cancer cell death. In vitro, the combination of CE-virus and CPT-11 killed more K-562 cancer cells than its non-CE counterpart and CPT-11.

Cancer

Oncolytic virus

Vaccinia virus

Carboxylesterase

Irinotecan

CPT-11

Gene-directed enzyme prodrug therapy

Vascular endothelial growth factor

Angiogenesis

Virus delivery

Virus spread

Plaque purification

Virus aggregation

Virus filtration

The Combination of Carboxylesterase-Expressing Oncolytic Vaccinia Virus and Irinotecan

Becker, Michelle Caitlin

14 January 2013

This project combines oncolytic Vaccinia virus (VV) with irinotecan (CPT-11) for the treatment of cancer. VV can infect, replicate in and destroy cancer cells, yet leave healthy cells relatively unaffected. CPT-11 is a chemotherapeutic of which ~5% is converted to the more active chemotherapeutic SN-38 by endogenous carboxylesterase (CE) enzymes. SN-38 is a topoisomerase I inhibitor that induces DNA double strand breaks, leading to growth arrest and apoptosis. Consequently, VV has been engineered to express a more effective isoform of the CE enzyme. The virus’ tumour tropism should restrict enhanced conversion of CPT-11 to the tumour. Neither CPT-11 nor SN-38 interfered with VV replication or spread. Engineered recombinants expressed CE enzyme which, when combined with CPT-11, produced DNA double strand breaks and cancer cell death. In vitro, the combination of CE-virus and CPT-11 killed more K-562 cancer cells than its non-CE counterpart and CPT-11.

Cancer

Oncolytic virus

Vaccinia virus

Carboxylesterase

Irinotecan

CPT-11

Gene-directed enzyme prodrug therapy

Vascular endothelial growth factor

Angiogenesis

Virus delivery

Virus spread

Plaque purification

Virus aggregation

Virus filtration

The Combination of Carboxylesterase-Expressing Oncolytic Vaccinia Virus and Irinotecan

Becker, Michelle Caitlin

January 2013

This project combines oncolytic Vaccinia virus (VV) with irinotecan (CPT-11) for the treatment of cancer. VV can infect, replicate in and destroy cancer cells, yet leave healthy cells relatively unaffected. CPT-11 is a chemotherapeutic of which ~5% is converted to the more active chemotherapeutic SN-38 by endogenous carboxylesterase (CE) enzymes. SN-38 is a topoisomerase I inhibitor that induces DNA double strand breaks, leading to growth arrest and apoptosis. Consequently, VV has been engineered to express a more effective isoform of the CE enzyme. The virus’ tumour tropism should restrict enhanced conversion of CPT-11 to the tumour. Neither CPT-11 nor SN-38 interfered with VV replication or spread. Engineered recombinants expressed CE enzyme which, when combined with CPT-11, produced DNA double strand breaks and cancer cell death. In vitro, the combination of CE-virus and CPT-11 killed more K-562 cancer cells than its non-CE counterpart and CPT-11.

Cancer

Oncolytic virus

Vaccinia virus

Carboxylesterase

Irinotecan

CPT-11

Gene-directed enzyme prodrug therapy

Vascular endothelial growth factor

Angiogenesis

Virus delivery

Virus spread

Plaque purification

Virus aggregation

Virus filtration