Gene transfer to the nervous system: prospects for novel treatments directed at diseases of the aging nervous system

Lentiviral vector mediates exogenous gene expression in adult rat DRG following peripheral nerve remote delivery

The primary sensory neurons with cell bodies in the dorsal root ganglion (DRG) have been extensively used as models in neurobiology and provide a useful model to study the mechanism of neural regeneration. Therefore, efficient and stable gene delivery to these postmitotic cells has significant therapeutic potential. Various studies involving the viral vector systems capable of neuronal transduction have been extensively evaluated in the cultured DRG neurons by adeno-associated virus. In the present study, we investigated the transduction performance of the lentiviral vector that mediates the catalytic subunit of protein kinase A (PKAc) and green fluorescent protein (GFP) expression in the DRG by sciatic nerve retrograde transport and tested whether PKAc expression in the DRG could inhibit the activation of RhoA after spinal cord injury. Five days after sciatic nerve remote delivery of lentiviral vector (LV)/PKAc-internal ribosome entry site (IRES)-GFP or LV/GFP, the L4-L6 DRGs were dissected for primary culture or immunostaining to observe the exogenous gene expression, or transecting the dorsal part of lumbar enlargement was performed, and 16 h later, the function of the exogenous gene was tested by RhoA pull-down analysis. The results showed that the lentiviral vector could mediate exogenous gene PKAc expression in the DRG and then inhibit spinal cord injury-induced RhoA activation by remote delivery of LV/PKAc-IRES-GFP through the sciatic nerve.

Progress in transduction of cerebellar Purkinje cells in vivo using viral vectors

Expression of a foreign gene in cerebellar Purkinje cells in vivo is a powerful method for exploring the pathophysiology of the cerebellum. Although using developmental engineering many gene-modified mice have been generated, this approach is time-consuming and requires a lot of effort for crossing different lines of mice, genotyping and maintenance of animals. If a gene of interest can be transferred to and efficiently expressed in Purkinje cells of developing and mature animals, it saves much time, effort and money. Recent advances in viral vectors have markedly contributed to selective and efficient gene transfer to Purkinje cells in vivo. There are two approaches for selective gene expression in Purkinje cells: one is to take advantage of the viral tropism for Purkinje cells, which includes the tropism of adeno-associated virus and the vesicular stomatitis virus glycoprotein (VSV-G)-pseudotyped lentivirus. Another method, which might be used in combination with the first one, is utilization of a Purkinje-cell-specific promoter. Focusing mainly on these points, recent progress in viral-vector-mediated transduction of Purkinje cells in vivo is reviewed.

Herpes simplex virus vector-mediated delivery of glial cell line-derived neurotrophic factor rescues erectile dysfunction following cavernous nerve injury

Erectile dysfunction (ED) is frequently associated with injury to the cavernous nerve sustained during pelvic surgery. Functional recovery from cavernous nerve injury is generally incomplete and occurs over an extended time frame. We employed a therapeutic gene transfer approach with herpes simplex virus (HSV) vector expressing glial cell line-derived neurotrophic factor (GDNF). Rat cavernous nerve was injured bilaterally using a clamp and dry ice. For HSV-treated groups, 20 microl of purified vector stock was administered directly to and around the damaged nerve. Delivery of an HSV vector expressing both green fluorescent protein (GFP) and lacZ (HSV-LacZ) was used as a control. Intracavernous pressure along with systemic arterial pressure (ICP/AP) was measured 2 and 4 weeks after the nerve injury. Fluorogold (FG) was injected into the penile crus 7 days before killing to assess nerve survival. Approximately 60% of major pelvic ganglion (MPG) cells were GFP positive after viral administration. At 4 weeks after nerve injury, rats treated with HSV-GDNF exhibited significant recovery of ICP/AP compared with control vector or untreated groups. The HSV-GDNF group also yielded more FG-positive MPG cells than the control vector group. HSV vector-mediated delivery of GDNF presents a viable approach for the treatment of ED following cavernous nerve injury.

Treatment of inflamed pancreas with enkephalin encoding HSV-1 recombinant vector reduces inflammatory damage and behavioral sequelae

This study assessed the efficacy of pancreatic surface delivered enkephalin (ENK)-encoding herpes simplex virus type 1 (HSV-1) on spontaneous behaviors and spinal cord and pancreatic enkephalin expression in an experimental pancreatitis model. Replication-defective HSV-1 with proenkephalin complementary DNA (cDNA) (HSV-ENK) or control beta-galactosidase cDNA (HSV-beta-gal), or media vehicle (Veh) was applied to the pancreatic surface of rats with dibutyltin dichloride (DBTC)-induced pancreatitis. Spontaneous exploratory behavioral activity was monitored on days 0 and 6 post DBTC and vector treatments. The pancreas, thoracic dorsal root ganglia (DRG, T9-10), and spinal cord (T9-10) were immunostained for met-enkephalin (met-ENK), beta-gal, and HSV-1 proteins. Spinal cord was also immunostained for c-Fos, and pancreas was stained for the inflammatory marker regulated on activation, normal T-cells expressed and secreted (RANTES), mu-opioid receptor, and hemotoxylin/eosin. On day 6, compared to pancreatitis and vector controls, the DBTC/HSV-ENK treated rats had significantly improved spontaneous exploratory activities, increased met-ENK staining in the pancreas and spinal cord, and normalized c-Fos staining in the dorsal horn. Histopathology of pancreas in DBTC/HSV-ENK treated rats showed preservation of acinar cells and cytoarchitecture with minimal inflammatory cell infiltrates, compared to severe inflammation and acinar cell loss seen in DBTC/HSV-beta-gal and DBTC/Veh treated rats. Targeted transgene delivery and met-ENK expression successfully produced decreased inflammation in experimental pancreatitis.

In vivo disposition and stability of DNA frayed wires in mice

DNA frayed wires (DNA(FW)) are an alternate form of DNA organization formed by the self-association of several strands of guanine-rich oligonucleotides. The purpose of this study was to define for the first time the blood clearance kinetics, tissue distribution, and stability of DNA(FW) in vivo in mice. Single bolus doses (1200 pmol/mouse) of (32)P-DNA(FW) and (32)P-random DNA were administered intravenously (IV) and intraperitoneally (IP) followed by scheduled blood, urine, fecal and tissue samplings. Blood clearance kinetics was described well by a first order two-compartment open model. The overall half-lives of elimination from the central compartment (T(1/2))(K10) were 3.57+/-0.1h for IV and 2.38+/-0.11 h for IP. In contrast, random DNA was completely degraded after 15 min regardless of the route of administration. Tissue distribution results demonstrated that DNA(FW) were primarily distributed and retained in the liver, intestines, kidneys, and heart. Low levels could also be detected in brain. Autoradiographs of blood, tissues, feces and urine extracts established that DNA(FW) remained intact after administration as no measurable levels of metabolites or degradation products were found after 24h. (32)P-DNA(FW) was primarily eliminated via hepato-biliary excretion into feces after either IV or IP administration (51.8+/-4.53% and 36.2+/-3.4%, respectively). The improved stability and longer half-life of DNA(FW), previously shown in vitro, is also seen in vivo, indicating that DNA(FW) may provide a stable delivery system for DNA gene therapies. In conclusion, this is the first study demonstrating the in vivo stability, pharmacokinetics, and disposition of DNA superstructures.

Polymeric gene carrier for insulin secreting cells: poly(L-lysine)-g-sulfonylurea for receptor mediated transfection

Ex vivo transfer of therapeutic genes to cells is one of the potential strategies to prolong the life span of cell transplants. However, relatively safe non-viral carriers have not been extensively investigated due to their lower transfection efficiency. In this study, poly(L-lysine)-g-sulfonylurea varying SU content (PLL-SU) was synthesized to promote gene delivery efficacy to an insulin secreting cell line, RINm5F, which is known to express sulfonylurea receptor (SUR). The polymer formed complexes with a model reporter gene of pCMV-Luc (DNA) and the size of resulting particles was around 100 nm. The transfection efficiency of a polymer synthesized with 5 mol% of SU in the reaction feed (PLL-SU5%) to RINm5F cell was at least 5 times higher than that of PLL. The cytotoxicity of PLL-SU5%/DNA complex was equivalent to that of PLL/DNA complex. PLL-SU5% showed less transfection efficiency than PLL to NIH3T3 and HepG2 cells which are SUR negative. In RINm5F cells, the addition of free SU decreased the transfection efficiency of PLL-SU5%/DNA complex, suggesting that the complex shares the same receptors for SU. The PLL-SU5%/DNA complex seems to be internalized via SUR-mediated endocytosis pathway as suggested by vacuolar ATPases inhibition by Bafilomycin A1. It is noted that RINm5F cells treated with PLL-SU5%/DNA complex secreted more insulin than control, untreated cells, suggesting the insulinotropic effect of SU in PLL-SU5%. In conclusion, PLL-SU may be useful for transfer of therapeutic genes into insulin secreting cells.

Herpes vector-mediated gene transfer in treatment of diseases of the nervous system

Vectors constructed from recombinant herpes simplex virus (HSV) have special utility for gene transfer to the nervous system. Nonreplicating vectors created by deletion of essential immediate early genes can be propagated to high titers on complementing cell lines that provide the missing gene product(s) in trans. Direct inoculation of these vectors into neural parenchyma is effective in rodent models of brain tumor, Parkinson disease, spinal cord injury, and spinal root trauma. Subcutaneous inoculation of the HSV vectors can be used to transduce neurons of the dorsal root ganglion to provide a therapeutic effect in models of polyneuropathy and chronic regional pain. In human trials, direct injection of replication-competent HSV into brain tumors has proven safe. Human trials of nonreplicating HSV gene transfer by direct inoculation for treatment of glioblastoma and HSV gene transfer by subcutaneous inoculation for the treatment of chronic intractable pain should commence soon.