Wim T.J.M.C. Hermens

Viral vectors, tools for gene transfer in the nervous system

Viral vectors are becoming increasingly important tools to investigate the function of neural proteins and to explore the feasibility of gene therapy to treat diseases of the nervous system. This gene transfer technology is based on the use of a virus as a gene delivery vehicle. In contrast to functional analysis of gene products in transgenic mouse, viral vectors can be applied to transfer genes to somatic, post-mitotic cells of fully developed animals. To date, five viral vector systems are available for gene transfer in the nervous system. These include recombinant and defective herpes viral vectors, adenoviral vectors, adeno-associated viral vectors and lentiviral vectors. Of these vectors herpes and adenoviral vectors are the most common in use. To date, one of the main hurdles in applying these two vector systems is the focal immune response that occurs following intraparenchymal infusion. Despite this limitation, herpes and adenoviral vectors have been used successfully to modify the physiological response to injury in several rodent models of neurodegeneration. The first purpose of this review is to describe the principles of the generation of viral vectors and to discuss the advantages and disadvantages of the viral vector systems currently in use for gene transfer in the nervous system. Secondly, we give an overview of the performance of these vectors following direct infusion in the nervous system and review the results obtained with these vectors in animal models of neurodegeneration and regeneration. The results of these initial studies have provided a framework for future experiments based on gene transfer strategies with viral vectors to study normal physiology and pathology of the nervous system.

Purification of recombinant adeno-associated virus by iodixanol gradient ultracentrifugation allows rapid and reproducible preparation of vector stocks for gene transfer in the nervous system.

Recombinant adeno-associated virus (rAAV) vectors have become attractive tools for in vivo gene transfer. The production and purification of high-titer rAAV vector stocks for experimental and therapeutic gene transfer continue to undergo improvement. Standard rAAV vector purification protocols include the purification of the vector by cesium chloride (CsCl)-density gradient centrifugation followed by extensive desalination via dialysis against a physiological buffer for in vivo use. These procedures are extremely time consuming and frequently result in a substantial loss of the infectious vector titer. As an alternative to CsCl we have investigated the use of Iodixanol, an X-ray contrast solution, as the density-gradient medium. Purification of rAAV vectors by Iodixanol shortened the centrifugation period to 3 hr and resulted in reproducible concentration and purification of rAAV-vector stocks. We show that injection of rAAV derived from an Iodixanol gradient can be used for in vivo gene transfer applications in the brain and spinal cord without detectable cytopathic effects and directing stable transgene expression for at least 2 months.

Mutant ubiquitin expressed in Alzheimer’s disease causes neuronal death1

Ubiquitin‐B+1 (UBB+1) is a mutant ubiquitin that accumulates in the neurones of patients with Alzheimers disease (AD). Here we report on the biochemical and functional differences between ubiquitin and UBB+1 and the effect of the mutant protein on neuronal cells. UBB+1 lacks the capacity to ubiquiti‐nate, and although it is ubiquitinated itself, UBB+1 is not degraded by the ubiquitin‐proteasomal system and is quite stable in neuronal cells. Overexpression of UBB+1 in neuroblastoma cells significantly induces nuclear fragmentation and cell death. Our results demonstrate that accumulation of UBB+1 in neurones is detrimental and may contribute to neuronal dysfunction in AD patients.—de Vrij, F. M. S., Sluijs, J. A., Gregori, L., Fischer, D. F., Hermens, W. T. J. M. C., Goldgaber, D., Verhaagen, J., van Leeuwen, F. W., Hol, E. M. Mutant ubiquitin expressed in Alzheimers disease causes neuronal death. FASEB J. 15, 2680–2688 (2001)

Rescue and sprouting of motoneurons following ventral root avulsion and reimplantation combined with intraspinal adeno-associated viral vector-mediated expression of glial cell line-derived neurotrophic factor or brain-derived neurotrophic factor

Following avulsion of a spinal ventral root, motoneurons that project through the avulsed root are axotomized. Avulsion between, for example, L2 and L6 leads to denervation of hind limb muscles. Reimplantation of an avulsed root directed to the motoneuron pool resulted in re-ingrowth of some motor axons. However, most motoneurons display retrograde atrophy and subsequently die. Two neurotrophic factors, glial cell line-derived neurotrophic factor (GDNF) and brain-derived neurotrophic factor (BDNF), promote the survival of motoneurons after injury. The long-term delivery of these neurotrophic factors to the motoneurons in the ventral horn of the spinal cord is problematic. One strategy to improve the outcome of the neurosurgical reinsertion of the ventral root following avulsion would involve gene transfer with adeno-associated viral (AAV) vectors encoding these neurotrophic factors near the denervated motoneuron pool. Here, we show that AAV-mediated overexpression of GDNF and BDNF in the spinal cord persisted for at least 16 weeks. At both 1 and 4 months post-lesion AAV-BDNF- and -GDNF-treated animals showed an increased survival of motoneurons, the effect being more prominent at 1 month. AAV vector-mediated overexpression of neurotrophins also promoted the formation of a network of motoneuron fibers in the ventral horn at the avulsed side, but motoneurons failed to extent axons into the reinserted L4 root towards the sciatic nerve nor to improve functional recovery of the hind limbs. This suggests that high levels of neurotrophic factors in the ventral horn promote sprouting, but prevent directional growth of axons of a higher number of surviving motoneurons into the implanted root.

Transient gene transfer to neurons and glia: Analysis of adenoviral vector performance in the CNS and PNS

In this paper a detailed protocol is presented for neuroscientists planning to start work on first generation recombinant adenoviral vectors as gene transfer agents for the nervous system. The performance of a prototype adenoviral vector encoding the bacterial lacZ gene as a reporter was studied, following direct injection in several regions of the central and peripheral nervous system. The distribution of the cells expressing the transgene appears to be determined by natural anatomical boundaries and possibly by the degree of myelinization of a particular brain region. In highly myelinated areas with a compact cellular structure (e.g. the cortex and olfactory bulb) the spread of the viral vector is limited to the region close to the injection needle, while in areas with a laminar structure (e.g. the hippocampus and the eye) more widespread transgene expression is observed. Retrograde transport of the viral vector may serve as an attractive alternative route of transgene delivery. A time course of expression of beta-galactosidase in neural cells in the facial nucleus revealed high expression during the first week after AdLacZ injection. However, a significant decline in transgene expression during the second and third week was observed. This may be caused by an immune response against the transduced cells or by silencing of the cytomegalovirus promoter used to drive transgene expression. Taken together, the data underscore that for each application of adenoviral vectors as gene transfer agents in the nervous system it is important to examine vector spread in and infectability of the neural structure that is subject to genetic modification.

Cells in human postmortem brain tissue slices remain alive for several weeks in culture

Animal models for human neurological and psychiatric diseases only partially mimic the underlying pathogenic processes. Therefore, we investigated the potential use of cultured postmortem brain tissue from adult neurological patients and controls. The present study shows that human brain tissue slices obtained by autopsy within 8 h after death can be maintained in vitro for extended periods (up to 78 days) and can be manipulated experimentally. We report for the first time that 1) neurons and glia in such cultures could be induced to express the reporter gene LacZ after transduction with adeno‐associated viral vectors and 2) cytochrome oxidase activity could be enhanced by the addition of pyruvate to the medium. These slice cultures offer new opportunities to study the cellular and molecular mechanisms of neurological and psychiatric diseases and new therapeutic strategies.— Verwer, R. W. H., Hermens, W. T. J. M. C. Dijkhuizen, P. A., ter Brake, O., Baker, R. E., Salehi, A., Sluiter, A. A., Kok, M. J. M., Müller, L. J., Verhaagen, J., Swaab, D. F. Cells in human postmortem brain tissue slices remain alive for several weeks in culture. FASEB J. 16, 54–60 (2002)

Adeno-associated viral vector-mediated gene transfer of brain-derived neurotrophic factor reverses atrophy of rubrospinal neurons following both acute and chronic spinal cord injury.

Rubrospinal neurons (RSNs) undergo marked atrophy after cervical axotomy. This progressive atrophy may impair the regenerative capacity of RSNs in response to repair strategies that are targeted to promote rubrospinal tract regeneration. Here, we investigated whether we could achieve long-term rescue of RSNs from lesion-induced atrophy by adeno-associated viral (AAV) vector-mediated gene transfer of brain-derived neurotrophic factor (BDNF). We show for the first time that AAV vectors can be used for the persistent transduction of highly atrophic neurons in the red nucleus (RN) for up to 18 months after injury. Furthermore, BDNF gene transfer into the RN following spinal axotomy resulted in counteraction of atrophy in both the acute and chronic stage after injury. These novel findings demonstrate that a gene therapeutic approach can be used to reverse atrophy of lesioned CNS neurons for an extended period of time.

Efficient delivery of Cre-recombinase to neurons in vivo and stable transduction of neurons using adeno-associated and lentiviral vectors

BackgroundInactivating genes in vivo is an important technique for establishing their function in the adult nervous system. Unfortunately, conventional knockout mice may suffer from several limitations including embryonic or perinatal lethality and the compensatory regulation of other genes. One approach to producing conditional activation or inactivation of genes involves the use of Cre recombinase to remove loxP-flanked segments of DNA. We have studied the effects of delivering Cre to the hippocampus and neocortex of adult mice by injecting replication-deficient adeno-associated virus (AAV) and lentiviral (LV) vectors into discrete regions of the forebrain.ResultsRecombinant AAV-Cre, AAV-GFP (green fluorescent protein) and LV-Cre-EGFP (enhanced GFP) were made with the transgene controlled by the cytomegalovirus promoter. Infecting 293T cells in vitro with AAV-Cre and LV-Cre-EGFP resulted in transduction of most cells as shown by GFP fluorescence and Cre immunoreactivity. Injections of submicrolitre quantities of LV-Cre-EGFP and mixtures of AAV-Cre with AAV-GFP into the neocortex and hippocampus of adult Rosa26 reporter mice resulted in strong Cre and GFP expression in the dentate gyrus and moderate to strong labelling in specific regions of the hippocampus and in the neocortex, mainly in neurons. The pattern of expression of Cre and GFP obtained with AAV and LV vectors was very similar. X-gal staining showed that Cre-mediated recombination had occurred in neurons in the same regions of the brain, starting at 3 days post-injection. No obvious toxic effects of Cre expression were detected even after four weeks post-injection.ConclusionAAV and LV vectors are capable of delivering Cre to neurons in discrete regions of the adult mouse brain and producing recombination.

Continuous renewal of the axonal pathway sensor apparatus by insertion of new sensor molecules into the growth cone membrane

BACKGROUND Growth cones at the tips of growing axons move along predetermined pathways to establish synaptic connections between neurons and their distant targets. To establish their orientation, growth cones continuously sample for, and respond to, guidance information provided by cell surfaces and the extracellular matrix. To identify specific guidance cues, growth cones have sensor molecules on their surface, which are expressed differentially during the temporospatial progress of axon outgrowth, at levels that depend on the pattern of neural activity. However, it has not been elucidated whether a change in gene expression can indeed change the molecular composition and, hence, the function of the sensor apparatus of growth cones. RESULTS We have constructed adenoviral gene transfer vectors of the chicken growth cone sensor molecules axonin-1 and Ng-CAM. Using these vectors, we initiated the expression of axonin-1 and Ng-CAM in rat dorsal root ganglia explants during ongoing neurite outgrowth. Using specific surface immunodetection at varying time points after infection, we found that axonin-1 and Ng-CAM are transported directly to the growth cone and inserted exclusively in the growth cone membrane and not in the axolemma of the axon shaft. Furthermore, we found that axonin-1 and Ng-CAM do not diffuse retrogradely, suggesting that the sensor molecules are integrated into multimolecular complexes in the growth cone. CONCLUSIONS During axon outgrowth, the pathway sensor apparatus of the growth cone is continuously updated by newly synthesized sensor molecules that originate directly from the transcription/translation machinery. Changes in the expression of sensor molecules may have a direct impact, therefore, on the exploratory function of the growth cone.

Tropism of AAV-2 vectors for neurons of the globus pallidus

A recombinant AAV-2 vector encoding the green fluorescent protein (gfp) under the control of the cytomegalovirus (CMV) promoter was injected into the striatum at varying antero-posterior coordinates. When the virus was delivered to the anterior part of the striatum, transduction efficiency was low and limited to the vicinity of the needle tract. In contrast, after injection into the posterior part of the striatum, in addition to a localized transduced area in the striatum, efficient and widespread transduction was observed at distance from the injection site, in the globus pallidus. In the latter case, labelled cells were also detected in the internal capsule and in the stria terminalis. The number of transduced cells in the striatum increased up to 1 month and then decreased whereas in the globus pallidus, transduction was maximal as early as 2 weeks post-injection. In the striatum and in the globus pallidus, the labelled cells had a neuron-like morphology. In contrast, in the internal capsule, labelled cells had a glial-like morphology.