Retinal ganglion cell differentiation in cultured mouse retinal explants

The availability of genetically engineered mice harboring specific mutations in genes affecting one or more retinal cell types affords new opportunities for investigating the genetic regulatory mechanisms of vertebrate retina formation. When identifying critical regulatory genes involved in retina development it is often advantageous to complement in vivo analysis with in vitro characterization. In particular, by combining classical techniques of retinal explant culturing with gene transfer procedures relying on herpes simple virus (HSV) amplicon vectors, gain-of-function analysis with genes of interest can be performed quickly and efficiently. Here, details are provided for isolating and culturing explants containing retinal progenitor cells and for infecting the explants with HSV expression vectors that perturb or rescue retinal ganglion cells, the first cell type to differentiate in the retina. In addition, the availability of sensitive techniques to monitor gene expression, including detection of reporter gene expression using antibodies and detection of endogenous marker gene expression using quantitative RT-PCR, provides an effective means for comparing wild-type and mutant retinas from genetically engineered mice.     

Targeting HSV amplicon vectors

Several techniques have been developed to deliver DNA directly into mammalian cells, spanning in difficulty from simple mixing procedures to complex systems requiring expensive equipment. Viral vectors have proven able to deliver genes into mammalian cells with high efficiency and low toxicity. In particular, herpes simplex virus type-1 (HSV-1) amplicon vectors are well suited for gene transfer studies as they can infect many cell types, both non-dividing and dividing, have a large transgene capacity and are easy to manipulate. For some applications, it may be desirable to target gene delivery to specific cell populations or to transduce normally non-susceptible cells. This can be achieved by modifying one or more of the glycoproteins found in the viral envelope. Glycoprotein C (gC) has a well-characterized heparan sulfate binding domain (HSBD) necessary for HSV binding to cells. Replacing this region with unique ligands can result in less efficient binding to natural target cells and increase binding to cells which express receptors for these ligands. A method to retarget amplicon vectors by replacing gC HSBD with a model ligand, the hexameric histidine-tag, is described, as well as means to evaluate the binding of modified vector as compared to wild-type virus to cells with or without the appropriate receptor, in this case, a his-tag pseudo-receptor. This protocol demonstrates increased binding of modified virus to receptor-positive cells (at levels greater than wild-type) with no loss of infectivity. Retargeted vectors can provide an additional tool for increasing the efficiency of gene delivery to specific cell types.     

Adeno-associated virus vectors for gene transfer to the brain

Gene therapy is a novel method under investigation for the treatment of neurological disorders. Considerable interest has focused on the possibility of using viral vectors to deliver genes to the central nervous system. Adeno-associated virus (AAV) is a potentially useful gene transfer vehicle for neurologic gene therapies. The advantages of AAV vector include the lack of any associated disease with a wild-type virus, the ability to transduce nondividing cells, the possible integration of the gene into the host genome, and the long-term expression of transgenes. The development of novel therapeutic strategies for neurological disorder by using AAV vector has an increasing impact on gene therapy research. This article describes methods that can be used to generate rodent and nonhuman primate models for testing treatment strategies linked to pathophysiological events in the ischemic brain and neurodegenerative disorders such as Parkinson's disease.     

Viral Vectors for Gene Delivery and Expression in the CNS

Viral vectors have emerged as an important tool for manipulating gene expression in the adult mammalian brain. The adult brain is composed largely of nondividing cells, and therefore DNA viruses have become the vehicle of choice for neurobiologists interested in somatic gene transfer. Recombinant viral vectors based upon adenovirus or herpes simplex virus have been created in which a gene essential for viral replication is removed and a gene of interest is inserted in the viral genome. While this eliminates pathogenicity due to viral replication, retention of viral genes and continued expression of these genes may limit the potential of the current generation of vectors. Defective viral vectors represent a different approach, in which only viral recognition signals are used to allow packaging of foreign DNA into a viral coat while eliminating the possibility of viral gene expression within target cells. The defective HSV vector has been used to transfer genes into the adult rat brain. This vector has also been used for analysis of the preproenkephalin promoterin vivo,and important regions of this promoter have been identified using this technique. A modification ofin situPCR has been developed as an adjunctive tool for sensitively documenting the presence of vector DNA within target cells duringin vivopromoter studies. Finally, the adenoassociated virus vector has been used as the first fully defective DNA viral vector, which also eliminates any contamination by helper viruses. This vector can transfer genes into the mammalian brain and has shown significant behavioral recovery in a rodent model of Parkinson's disease. Future work will undoubtedly result in still more diverse and improved vectors; however, these studies have documented the importance of viral vectors to both basic neurobiology and the potential treatment of neurologic disease.     

Herpes simplex virus type 1/adeno-associated virus rep(+) hybrid amplicon vector improves the stability of transgene expression in human cells by site-specific integration

Herpes simplex virus type 1 (HSV-1) amplicon vectors are promising gene delivery tools, but their utility in gene therapy has been impeded to some extent by their inability to achieve stable transgene expression. In this study, we examined the possibility of improving transduction stability in cultured human cells via site-specific genomic integration mediated by adeno-associated virus (AAV) Rep and inverted terminal repeats (ITRs). A rep(-) HSV/AAV hybrid amplicon vector was made by inserting a transgene cassette flanked with AAV ITRs into an HSV-1 amplicon backbone, and a rep(+) HSV/AAV hybrid amplicon was made by inserting rep68/78 outside the rep(-) vector 3' AAV ITR sequence. Both vectors also had a pair of loxP sites flanking the ITRs. The resulting hybrid amplicon vectors were successfully packaged and compared to a standard amplicon vector for stable transduction frequency (STF) in human 293 and Gli36 cell lines and primary myoblasts. The rep(+), but not the rep(-), hybrid vector improved STF in all three types of cells; 84% of Gli36 and 40% of 293 stable clones transduced by the rep(+) hybrid vector integrated the transgene into the AAVS1 site. Due to the difficulty in expanding primary myoblasts, we did not assess site-specific integration in these cells. A strategy to attempt further improvement of STF by "deconcatenating" the hybrid amplicon DNA via Cre-loxP recombination was tested, but it did not increase STF. These data demonstrate that introducing the integrating elements of AAV into HSV-1 amplicon vectors can significantly improve their ability to achieve stable gene transduction by conferring the AAV-like capability of site-specific genomic integration in dividing cells.     

Glycoproteins E and I facilitate neuron-to-neuron spread of herpes simplex virus.

Two herpes simplex virus (HSV) glycoproteins E and I (gE and gI) form a heterooligomer which acts as an Fc receptor and also facilitates cell-to-cell spread of virus in epithelial tissues and between certain cultured cells. By contrast, gE-gI is not required for infection of cells by extracellular virus. HSV glycoproteins gD and gJ are encoded by neighboring genes, and gD is required for both virus entry into cells and cell-to-cell spread, whereas gJ has not been shown to influence these processes. Since HSV infects neurons and apparently spreads across synaptic junctions, it was of interest to determine whether gD, gE, gI and gJ are also important for interneuronal transfer of virus. We tested the roles of these glycoproteins in neuron-to-neuron transmission of HSV type 1 (HSV-1) by injecting mutant viruses unable to express these glycoproteins into the vitreous body of the rat eye. The spread of virus infection was measured in neuron-rich layers of the retina and in the major retinorecipient areas of the brain. Wild-type HSV-1 and a gJ- mutant spread rapidly between synaptically linked retinal neurons and efficiently infected major retinorecipient areas of the brain. gD mutants, derived from complementing cells, infected only a few neurons and did not spread in the retina or brain. Mutants unable to express gE or gI were markedly restricted in their ability to spread within the retina, produced 10-fold-less virus in the retina, and spread inefficiently to the brain. Furthermore, when compared with wild-type HSV-1, gE- and gI- mutants spread inefficiently from cell to cell in cultures of neurons derived from rat trigeminal ganglia. Together, our results suggest that the gE-gI heterooligomer is required for efficient neuron-to-neuron transmission through synaptically linked neuronal pathways.     

Gene delivery using herpes simplex virus vectors

Herpes simplex virus (HSV) is a neurotropic DNA virus with many favorable properties as a gene delivery vector. HSV is highly infectious, so HSV vectors are efficient vehicles for the delivery of exogenous genetic material to cells. Viral replication is readily disrupted by null mutations in immediate early genes that in vitro can be complemented in trans, enabling straightforward production of high-titre pure preparations of non-pathogenic vector. The genome is large (152 Kb) and many of the viral genes are dispensable for replication in vitro, allowing their replacement with large or multiple transgenes. Latent infection with wild-type virus results in episomal viral persistence in sensory neuronal nuclei for the duration of the host lifetime. Transduction with replication-defective vectors causes a latent-like infection in both neural and non-neural tissue; the vectors are non-pathogenic, unable to reactivate and persist long-term. The latency active promoter complex can be exploited in vector design to achieve long-term stable transgene expression in the nervous system. HSV vectors transduce a broad range of tissues because of the wide expression pattern of the cellular receptors recognized by the virus. Increasing understanding of the processes involved in cellular entry has allowed preliminary steps to be taken towards targeting the tropism of HSV vectors. Using replication-defective HSV vectors, highly encouraging results have emerged from recent pre-clinical studies on models of neurological disease, including glioma, peripheral neuropathy, chronic pain and neurodegeneration. Consequently, HSV vectors encoding appropriate transgenes to tackle these pathogenic processes are poised to enter clinical trials.     

Herpes simplex virus vectors for gene therapy

Herpes simplex virus (HSV) has a number of advantages as a vector for delivering specific genes to the nervous system. These include its large size, wide host range, and its ability to establish long-lived asymptomatic infections in neuronal cells in which a specific region of the viral genome continues to be expressed. Unfortunately, the large size of this virus and difficulty in manipulating it has led to its use as a vector lagging behind that of other, smaller viruses such as the retroviruses. In addition, the virus's ability to replicate lytically in the brain, under some circumstances, causing encephalitis, has led to fears about its potential safety for ultimate use in humans. This review will discuss a number of new approaches that are aimed at rendering simpler the insertion of foreign genes into the virus and making it as safe as possible. Ultimately, these advances offer real hope for the use of HSV vectors in gene therapy procedures.     

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.     

Expression of multiple proteins within single primary cortical neurons using a replication deficient HSV vector

The study of protein-protein interactions in the nervous system has become dependent on the ability to express foreign proteins (or to overexpress endogenous proteins) within neurons. Often, multiple genes need to be overexpressed in the same cell. To investigate the simultaneous co-expression of more than one virally introduced gene in primary cortical neurons, we infected cultures with two different herpes simplex virus (HSV) vectors and analyzed the proportion of singly and doubly infected cells. The vast majority of neurons expressed both gene products, with a smaller number expressing one or the other protein alone. Increasing the quantity of virus caused an increase in the proportion of doubly labeled cells at the expense of singly labeled cells, which is consistent with a model in which infection with one viral vector is independent of infection with the other. We conclude that co-infection with HSV vectors is an efficient way to obtain expression of multiple gene products within individual primary culture neurons.     

Evaluation of infection parameters in the production of replication-defective HSV-1 viral vectors

Herpes simplex virus type-1 (HSV-1) is a neurotrophic human pathogen that establishes life-long latency in the nervous system. Our laboratory has extensively engineered this virus to retain the ability to persist in neurons without expression of lytic genes or disease phenotype. Highly defective, replication-incompetent HSV mutants are thus potentially ideal for transfer of therapeutic transgenes to human nerves where long-term therapy of nervous system disease may be provided. A prerequisite for using recombinant HSV vectors for therapeutic gene delivery to humans is the development of methods for large-scale manufacture of HSV vectors. Here we report studies to identify infection parameters that result in high-yield production of immediate early gene deletion mutant HSV vectors in complementing cells that supply the deleted essential viral functions in trans. Virus yield was correlated with various culture media conditions that included pH, glucose metabolism, and serum levels. The results demonstrated that systematic media exchange to remove lactate derived from high-level glucose consumption, maintenance of tissue culture pH at 6.8, and the use of 5% fetal bovine serum gave the highest yield of infectious virus. The data indicate that these are important parameters to consider for high-yield, large-scale virus production.     

An Enhanced Packaging System for Helper-Dependent Herpes Simplex Virus Vectors

Helper-dependent herpes simplex virus (HSV) vectors (amplicons) show considerable promise to provide for long-term transduced-gene expression in most cell types. The current packaging system of choice for these vectors involves cotransfection with a set of five overlapping cosmids that encode the full HSV type 1 (HSV-1) helper virus genome from which the packaging (pac) elements have been deleted. Although both the helper virus and the HSV amplicon can replicate, only the latter is packaged into infectious viral particles. Since the titers obtained are too low for practical application, an enhanced second-generation packaging system was developed by modifying both the helper virus and the HSV amplicon vector. The helper virus was reverse engineered by using the original five cosmids to generate a single HSV-bacterial artificial chromosome (BAC) clone in Escherichia coli from which the pac elements were deleted to generate a replication-proficient but packaging-defective HSV-1 genome. The HSV amplicon was modified to contain the simian virus 40 origin of replication, which acts as an HSV-independent replicon to provide for the replicative expansion of the vector. The HSV amplicon is packaged into infectious particles by cotransfection with the HSV-BAC helper virus into the 293T cell line, and the resulting cell lysate is free of detectable helper virus contamination. The combination of both modifications to the original packaging system affords an eightfold increase in the packaged-vector yield.     

In vitro and in vivo gene delivery by recombinant baculoviruses

Although recombinant baculovirus vectors can be an efficient tool for gene transfer into mammalian cells in vitro, gene transduction in vivo has been hampered by the inactivation of baculoviruses by serum complement. Recombinant baculoviruses possessing excess envelope protein gp64 or other viral envelope proteins on the virion surface deliver foreign genes into a variety of mammalian cell lines more efficiently than the unmodified baculovirus. In this study, we examined the efficiency of gene transfer both in vitro and in vivo by recombinant baculoviruses possessing envelope proteins derived from either vesicular stomatitis virus (VSVG) or rabies virus. These recombinant viruses efficiently transferred reporter genes into neural cell lines, primary rat neural cells, and primary mouse osteal cells in vitro. The VSVG-modified baculovirus exhibited greater resistance to inactivation by animal sera than the unmodified baculovirus. A synthetic inhibitor of the complement activation pathway circumvented the serum inactivation of the unmodified baculovirus. Furthermore, the VSVG-modified baculovirus could transduce a reporter gene into the cerebral cortex and testis of mice by direct inoculation in vivo. These results suggest the possible use of the recombinant baculovirus vectors in combination with the administration of complement inhibitors for in vivo gene therapy.     

Lentiviral and MLV based retroviral vectors for ex vivo and in vivo gene transfer

Retroviral vectors have become an important tool for gene transfer in vitro and in vivo. Classical Moloney murine leukemia virus (MLV) based retroviral vectors have been used for over 20 years to transfer genes into dividing cells. Cell lines for production of retroviral vectors have become commonly available and modifications in retroviral vector design and use of envelope proteins have made the production of high titer, helper-free, infectious virus stocks relatively easy. More recently, lentiviral vectors, another class of retroviruses, have been modified for in vitro and in vivo gene transfer. The ability of lentiviral vectors to transduce non-dividing cells has made them especially attractive for in vivo gene transfer into differentiated, non-dividing tissues. Several improvements in helper plasmids and vectors have made lentivirus a safe vector system for ex vivo and in vivo gene transfer. This review will briefly summarize the background of these vector systems and provide some common protocols available for the preparation of MLV based retroviral vectors and HIV-1 based lentiviral vectors.     

Gene delivery and gene therapy with herpes simplex virus-based vectors

The development of efficient means of delivery genes in vivo is essential both for testing gene function in the intact animal and for human gene therapy procedures. A number of viral and non-viral gene delivery methods have been developed for this purpose. Of those herpes simplex virus (HSV)-based vectors have particular advantages for gene delivery to the nervous system including their ability to infect non-dividing neurones and establish asymptomatic latent infections. Moreover, considerable progress has been made, firstly, in disabling HSV vectors so as to prevent the damaging effects of wild type virus and secondly, to ensure long-term expression of the inserted transgene(s). These vectors thus offer a valuable tool for testing gene function in neuronal cells in vivo and may ultimately be safe enough for use in human gene therapy procedures.     

Lentiviral vectors for treating and modeling human CNS disorders

Vectors based on lentiviruses efficiently deliver genes into many different types of primary neurons from a broad range of species including man and the resulting gene expression is long term. These vectors are opening up new approaches for the treatment of neurological diseases such as Parkinson's disease (PD), Huntington's disease (HD), and motor neuron diseases (MNDs). Numerous animal studies have now been undertaken with these vectors and correction of disease models has been obtained. Lentiviral vectors also provide a new strategy for in vivo modeling of human diseases; for example, the lentiviral-mediated overexpression of mutated human alpha-synuclein or huntingtin genes in basal ganglia induces neuronal pathology in animals resembling PD and HD in man. These vectors have been refined to a very high level and can be produced safely for the clinic. This review will describe the general features of lentiviral vectors with particular emphasis on vectors derived from the non-primate lentivirus, equine infectious anemia virus (EIAV). It will then describe some key examples of genetic correction and generation of genetic animal models of neurological diseases. The prospects for clinical application of lentiviral vectors for the treatment of PD and MNDs will also be outlined.