Bioluminescence imaging after HSV amplicon vector delivery into brain

BACKGROUND: Firefly luciferase (Fluc) has routinely been used to quantitate and analyze gene expression in vitro by measuring the photons emitted after the addition of ATP and luciferin to a test sample. It is now possible to replace luminometer-based analysis of luciferase activity and measure luciferase activity delivered by viral vectors directly in live animals over time using digital imaging techniques. METHODS: An HSV amplicon vector expressing Fluc cDNA from an inducible promoter was delivered to cells in culture and into the mouse brain. In culture, expression of Fluc was measured after induction in a dose-dependent manner by a biochemical assay, and then confirmed by Western blot analysis and digital imaging. The vectors were then stereotactically injected into the mouse brain and Fluc expression measured non-invasively using bioluminescence imaging. RESULTS: Rapamycin-mediated induction of Fluc from an HSV amplicon vector in culture resulted in dose-dependent expression of Fluc when measured using a luminometer and by digital analysis. In mouse cortex, a single injection of an HSV amplicon vector (2 microl, 1x10(8) transducing units (t.u.)/ml) expressing Fluc from a viral promoter (CMV) was sufficient to detect robust luciferase activity for at least 1 week. Similarly, an HSV amplicon vector expressing Fluc under an inducible promoter was also detectable in the mouse cortex after a single dose (2 microl, 1x10(8) t.u./ml) for up to 5 days, with no detectable signal in the uninduced state. CONCLUSIONS: This HSV amplicon vector-based system allows for fast, non-invasive, semi-quantitative analysis of gene expression in the brain.     

Targeting vectors for intracellular immunisation

We define intracellular immunization as the inhibition or inactivation of the function of a molecule by the ectopic intracellular expression of antibody binding domains which recognise the molecule. Such recombinant antibodies can be directed to different compartments of eukaryotic cells by means of previously defined targeting signals, thus permiting the study of any molecule in any cellular compartment for which an antibody is available. For this purpose, we have created a set of vectors based on the VHExpress vector described [Persic, L., Roberts, A., Wilton, J., Cattaneo, A., Bradbury, A. and Hoogenboom, H.R. (1997) An integrated vector system for the eukaryotic expression of antibodies or their fragments after selection from phage display libraries. Gene 187, 000–000], which has been modified to express scFvs (single chain fragments) linked to specific targeting signals. These permit the localisation of scFvs to different intracellular compartments: the endoplasmic reticulum (scFvE-er), the nucleus (scFvE-nuclear), the mitochondria (scFvE-mit), the cytoplasm (scFvE-cyto), and as secreted proteins (scFvE-sec). The function of these vectors has been assessed by the immunofluorescence of COS cells transiently transfected with constructs containing the αD11 scFv.     

Use of herpes virus amplicon vectors to study brain disorders

There is an enormous initiative to establish the genetic basis for disorders of brain function. Unfortunately, genetic intervention is not accomplished easily in the nervous system. One strategy is to engineer and deliver to neurons specialized viral vectors that carry a gene (or genes) of interest, thereby exploiting the natural ability of viruses to insert genetic material into cells. When delivered to brain cells, these vectors cause infected cells to increase the expression of the genes of interest. The ability to deliver genes into neurons in vitro and in vivo with herpes simplex virus (HSV) amplicon vectors has made it possible to carry out exactly these sorts of experiments. This technology has the potential to offer new insights into the etiology of a wide variety of neuropsychiatric disorders. We describe the use of HSV amplicon vectors to study Alzheimer disease, drug addiction, and depression, and discuss the considerations that enter into the use of these vectors both in vitro and in vivo. The HSV amplicon virus is a user-friendly vector for the delivery of genes into neurons that has come of age for the study of brain function.     

Gene transfer into Purkinje cells using herpesviral amplicon vectors in cerebellar cultures

Purkinje cells play a crucial role in sensory motor coordination since they are the only output projection neurons in the cerebellar cortex and are affected in most spinocerebellar ataxias. They stand out in the central nervous system due to their large size and their profusely branched dendritic arbor. However, molecular and cellular studies on Purkinje cells are often hampered by the difficulty of maintaining these cells in culture. Here we report an easy, robust and reproducible method to obtain Purkinje-enriched mixed cerebellar cell cultures from day 16 mouse embryos using papain digestion and a semi-defined culture medium, being the composition of the culture approximately 20% Purkinje cells, 70% non-Purkinje neurons and 10% glial cells. We demonstrate that efficient gene transfer into Purkinje cells (as well as into other cerebellar populations) is possible using herpes simplex virus-1 (HSV-1)-derived vectors. Indeed, up to 50% of the Purkinje cells can be transduced and gene expression may persist for at least 14 days. As a result, this procedure permits functional gene expression studies to be carried out on cultured Purkinje neurons. To demonstrate this, we show that the expression of a dominant-negative form of glycogen synthase kinase-3 protects Purkinje neurons against cell death triggered by a chemical inhibitor of phosphatidylinositol-3 kinase. In summary, we have established reproducible and reliable cerebellar cell cultures enriched for Purkinje cells which enables gene transfer studies to be carried out using herpesviral vectors.     

In vivo interleukin-2 gene therapy of established tumors with herpes simplex amplicon vectors

In vivo cytokine gene transfer may greatly simplify autologous tumor vaccine production. Herpes simplex viral amplicon vectors (HSV) are efficient gene-transfer vehicles and may overcome many limitations of prior gene-transfer methods. The interleukin-2 (IL-2) and β-galactosidase genes (lac) were inserted into an HSV amplicon vector and tested in a subcutaneous squamous cell carcinoma of lung origin to determine the efficiency of in vivo gene transfer and the utility of such a direct gene-transfer approach in cancer therapy. Gene transfer and expression were assessed by histochemical staining and enzyme-linked immunosorbent assay (ELISA). Growth of injected tumors as well as non-injected tumors remote from the site of injection was assessed. Assessment of lymphocytic infiltrates into tumors was performed by immunohistochemistry. Survival was recorded. Direct in vivo injection of established tumors with a HSVil2 resulted in efficient gene transfer and production of IL-2 in the injected tumor but not at tumors remote from the sites of injection. There was a significant suppression of growth of the tumors injected with HSVil2 (P < 0.01) when compared with tumors injected with HSV without il2. Of note, growth of tumors remote from sites of HSVil2 injection was also retarded and treatment was associated with a significant (P < 0.05) improvement in survival. Direct intratumoral administration of HSV amplicon vectors can result in efficient transfer of cytokine genes and have antitumor efficacy. HSV vectors are therefore potentially useful agents in such in vivo gene-therapy strategies and simplify cytokine antitumor gene-therapy strategies. Received: 19 June 1998 / Accepted: 25 September 1998     

HSV-1 HF株扩增子载体的构建及其在不同HSV血清型间的通用性研究

旨在构建HSV-1HF株的扩增子载体,研究其在不同血清型HSV辅助下的包装通用性。经酶切HF株的BAC-HSV-1,获得oriS和pac元件并测序。以pSilencer2.0-U6为骨架,以DsRed为报告基因构建HSV-1HF株的扩增子载体,利用脂质体2000转染扩增子载体至Vero细胞,分别应用HSV-1HF株和HSV-2HG52辅助HSV-1扩增子载体进行包装,待产生细胞病变效应后取上清,再次感染Vero细胞,观察Vero细胞内红色荧光蛋白表达情况。本研究首次构建了HSV-1HF株的扩增子载体,鉴定了HSV-1HF株oriS和pac元件,HSV-1HF株扩增子载体可以被HSV-1HF株和HSV-2HG52株包装并扩增。     

Targeting frequency for deletion vectors in embryonic stem cells.

We analyzed the gene targeting frequencies and recombination products generated by a series of replacement deletion vectors which target the hprt (hypoxanthine phosphoribosyltransferase) locus in mouse embryonic stem cells. We found that the targeting frequency of a 19.2-kb deletion was comparable to that of a 3-kb deletion or a conventional replacement event in which a 1.7-kb fragment was inserted into the locus. We also observed different integration patterns for these deletion vectors. A result of this finding is that a wide range of genomic deletions in embryonic stem cells is feasible.     

Augmentation of anti-tumor responses of adoptively transferred CD8+T cells in the lymphopenic setting by HSV amplicon transduction

Treatment of cancer with cytotoxic agents may induce lymphopenia. Adoptively transferred T cells have been reported to display enhanced anti-tumor efficacy in the lymphopenic setting. We reasoned that the anti-tumor effects of adoptively transferred cells in the lymphopenic host could be further augmented through local provision of an innate stimulus in the tumor bed. Utilizing a model in which mice were irradiated to induce lymphopenia, with limited shielding to allow tumor growth, we demonstrate that “triple” therapy consisting of radiation-induced lymphopenia, adoptive transfer of naïve CD8+ T cells, and intra-tumoral HSV amplicon injection resulted in reduced tumor growth compared to the combination of any two of the aforementioned interventions. To gain insight into the mechanism underlying this effect we studied the effects of HSV amplicon transduction into tumors on cytokine expression and on anti-tumor specific T cells. HSV amplicon transduction specifically induced several cytokine mRNAs including IFN-γ, and IP-10. Adoptively transferred transgenic OT-1 T cells directed against Ovalbumin were more effective against Ovalbumin-expressing tumors when combined with intra-tumoral HSV amplicon injections in the lymphopenic host. Following intra-tumoral HSV-amplicon injections, anti-tumor T cells secreted higher levels of interferon-γ in response to in-vitro re-stimulation with tumor cells, implying that HSV amplicon injection provided a strong signal for T cell activation. Combining adoptive transfer of naïve T cells in the lymphopenic setting with local T cell stimulation may facilitate expansion and activation of anti-tumor T cell populations in vivo, resulting in enhanced anti-tumor responses without the need to resort to prolonged in vitro T cell culture and/or manipulation.     

Generation of stable retrovirus packaging cell lines after transduction with herpes simplex virus hybrid amplicon vectors

Background

A number of properties have relegated the use of Moloney murine leukemia virus (Mo‐MLV)‐based retrovirus vectors primarily to ex vivo protocols. Direct implantation of retrovirus producer cells can bypass some of the limitations, and in situ vector production may result in a large number of gene transfer events. However, the fibroblast nature of most retrovirus packaging cells does not provide for an effective distribution of vector producing foci in vivo, especially in the brain. Effective development of new retrovirus producer cells with enhanced biologic properties may require the testing of a large number of different cell types, and a quick and efficient method to generate them is needed.

Methods

Moloney murine leukemia virus (Mo‐MLV) gag‐pol and env genes and retrovirus vector sequences carrying lacZ were cloned into different minimal HSV/AAV hybrid amplicons. Helper virus‐free amplicon vectors were used to co‐infect glioma cells in culture. Titers and stability of retrovirus vector production were assessed.

Results

Simultaneous infection of two glioma lines, Gli‐36 (human) and J3T (dog), with both types of amplicon vectors, generated stable packaging populations that produced retrovirus titers of 0.5–1.2×10⁵ and 3.1–7.1×10³ tu/ml, respectively. Alternatively, when cells were first infected with retrovirus vectors followed by infection with HyRMOVAmpho amplicon vector, stable retrovirus packaging populations were obtained from Gli‐36 and J3T cells producing retrovirus titers comparable to those obtained with a traditional retrovirus packaging cell line, ΨCRIPlacZ.

Conclusions

This amplicon vector system should facilitate generation of new types of retrovirus producer cells. Conversion of cells with migratory or tumor/tissue homing properties could result in expansion of the spatial distribution or targeting capacity, respectively, of gene delivery by retrovirus vectors in vivo. Copyright © 2002 John Wiley & Sons, Ltd.

     

HSV-1 amplicon vectors are a highly efficient gene delivery system for skeletal muscle myoblasts and myotubes

Analysis of RyR1 structure function inmuscle cells is made difficult by the low (<5%) transfectionefficiencies of myoblasts or myotubes using calcium phosphate orcationic lipid techniques. We inserted the full-length 15.3-kb RyR1cDNA into a herpes simplex virus type 1 (HSV-1) amplicon vector,pHSVPrPUC between the ori/IE 4/5 promoter sequence and theHSV-1 DNA cleavage/packaging signal (pac). pHSVGN andpHSVGRyR1, two amplicons that expressed green fluorescent protein, wereused for fluorescence-activated cell sorter analysis of transductionefficiency. All amplicons were packaged into HSV-1 virusparticles using a helper virus-free packaging system and yielded10⁶ transducing vector units/ml. HSVRyR1, HSVGRyR1, andHSVGN virions efficiently transduced mouse myoblasts and myotubes,expressing the desired product in 70-90% of the cells atmultiplicity of infection 5. The transduced cells appeared healthy andRyR1 produced by this method was targeted properly and restoredskeletal excitation-contraction coupling in dyspedic myotubes. Themyotubes produced sufficient protein to allow single-channel analysesfrom as few as 10 100-mm dishes. In most cases this method couldpreclude the need for permanent transfectants for the study of RyR1structure function.

     

Flow cytometric assessment of transduction efficiency and cytotoxicity of herpes simplex virus type 1-based amplicon vectors

BACKGROUND: In this study, we compared herpes simplex virus type 1 (HSV-1) amplicon vector stocks prepared by transient cotransfection with two different BAC-cloned packaging-defective HSV-1 helper genomes, fHSVDeltapacDelta27 and fHSVDeltapac, with respect to transduction efficiency and cytotoxicity. Both fHSVDeltapacDelta27 and fHSVDeltapac are packaging defective because the pac signals have been deleted; fHSVDeltapacDelta27 contains an additional deletion in the HSV-1 ICP27 gene, which increases the safety of the system. METHODS: HSV-1 amplicon pHSVGFP under the control of the HSV-1 immediate-early (IE) 4/5 promotor was packaged into virus particles by transient cotransfection with either fHSVDeltapacDelta27 or fHSVDeltapac DNA. Cultures were infected with the two different vector stocks and examined under the fluorescence microscope and analyzed by flow cytometry over a 5-day period to assess transduction efficiency and cytotoxicity. RESULTS: Both vector stocks, pHSVGFP[fHSVDeltapacDelta27] and pHSVGFP[fHSVDeltapac], efficiently transduced the target cells. Interestingly, the highest mean fluorescence intensities were measured at 1 day after infection, whereas the number of GFP-fluorescent cells reached a peak at day 3 after infection. At day 3 after infection, a slight increase in the number of dead cells was observed in those cultures transduced with high doses of vector stock. Between days 3 and 4 after infection, the number of dead cells increased dramatically in all the cultures, transduced and nontransduced. Only the cultures infected with a high dose of pHSVGFP[fHSVDeltapac] displayed a significant further increase in the number of dead cells between days 4 and 5 postinfection. CONCLUSIONS: Flow cytometry allowed comparison of transduction efficiency and cytotoxicity mediated by the two different amplicon vector stocks. Cultures infected with pHSVGFP[fHSVDeltapacDelta27] were more viable than those infected with pHSVGFP[fHSVDeltapac](P < 0.05). The practical implications of this study are at the level of vector design. Flow cytometry has proven a fast and reliable approach to assess the quality of potential gene transfer vectors prior to their use in (pre) clinical trials.     

Targeting vectors for gene diversification by meiotic recombination in Neurospora crassa.

We have constructed a pair of vectors, pDV2 and pDV3, that enable targeted insertion of exogenous DNA into Linkage Group I of Neurospora crassa at the his-3 locus. Transplaced sequences are inserted between his-3 and the cog(L) recombination hot spot and include his-3 mutations that allow meiotic recombination initiated by cog(L) to be monitored. Selection of correctly placed transforming DNA is based on complementation between different his-3 alleles borne by the plasmids and transformation hosts. The system allows investigation of the effect of any given sequence on recombination as well as diversification of sets of related sequences in vivo for directed evolution of genes.     

Targeting avian leukosis virus subgroup A vectors by using a TVA-VEGF bridge protein

Previously, we have demonstrated that bridge proteins comprised of avian leukosis virus (ALV) receptors fused to epidermal growth factor (EGF) can be used to selectively target retroviral vectors with ALV envelope proteins to cells expressing EGF receptors. To determine whether another type of ligand incorporated into an ALV receptor-containing bridge protein can also function to target retroviral infection, the TVA-VEGF110 bridge protein was generated. TVA-VEGF110 consists of the extracellular domain of the TVA receptor for ALV subgroup A (ALV-A), fused via a proline-rich linker peptide to a 110-amino-acid form of vascular endothelial growth factor (VEGF). This bridge protein bound specifically to its cell surface receptor, VEGFR-2, and efficiently mediated the entry of an ALV-A vector into cells. These studies indicate that ALV receptor-ligand bridge proteins may be generally useful tools for retroviral targeting approaches.     

Deletion of the virion host shutoff protein (vhs) from herpes simplex virus (HSV) relieves the viral block to dendritic cell activation: potential of vhs- HSV vectors for dendritic cell-mediated immunotherapy

Herpes simplex virus (HSV) infects dendritic cells (DC) efficiently but with minimal replication. HSV, therefore, appears to have evolved the ability to enter DC even though they are nonpermissive for virus growth. This provides a potential utility for HSV in delivering genes to DC for vaccination purposes and also suggests that the life cycle of HSV usually includes the infection of DC. However, DC infected with HSV usually lose the ability to become activated following infection (M. Salio, M. Cella, M. Suter, and A. Lanzavecchia, Eur. J. Immunol. 29:3245-3253, 1999; M. Kruse, O. Rosorius, F. Kratzer, G. Stelz, C. Kuhnt, G. Schuler, J. Hauber, and A. Steinkasserer, J. Virol. 74:7127-7136, 2000). We report that for DC to retain the ability to become activated following HSV infection, the virion host shutoff protein (vhs) must be deleted. vhs usually functions to destabilize mRNA in favor of the production of HSV proteins in permissive cells. We have found that it also plays a key role in the inactivation of DC and is therefore likely to be important for immune evasion by the virus. Here, vhs would be anticipated to prevent DC activation in the early stages of infection of an individual with HSV, reducing the induction of cellular immune responses and thus preventing virus clearance during repeated cycles of virus latency and reactivation. Based on this information, replication-incompetent HSV vectors with vhs deleted which allow activation of DC and the induction of specific T-cell responses to delivered antigens have been constructed. These responses are greater than if DC are loaded with antigen by incubation with recombinant protein.     

Targeting of the creatine kinase M gene in embryonic stem cells using isogenic and nonisogenic vectors.

Replacement vectors with genomic DNA originating from different mouse strains were used to introduce site-specific mutations into the creatine kinase M (CKM) gene of mouse embryonic stem (ES) cells. Here we demonstrate that in mouse strain 129-derived ES cells, the gene is at least 25-fold more efficiently targeted with an isogenic, 129-derived vector (129-pRV8.3) than with a nonisogenic, BALB/c-specific vector (BALB/c-pRV8.3). The two targeting constructs were identical except for allelic differences which were typed by partial sequencing. These included base pair mismatches (2%) and a polymorphic [GTC]-repeat length variation. Both in separate transfections as well as in cotransfections with mixed vectors, homologous disruption of the CKM gene resulted uniquely from the 129-isogenic DNA. Our data confirm earlier observations on requirements for homologous recombination in pro- and eukaryotic systems and indicate that targeting of the CKM locus is highly sensitive to small sequence differences between cognate segments in the endogenous and incoming DNA.