Alberto Auricchio

AAV2 Gene Therapy Readministration in Three Adults with Congenital Blindness

Repeat administration of gene therapy to the contralateral retina of three congenitally blind patients was safe and resulted in improved vision. Shining a Light with Gene Therapy Gene therapy has great potential for treating certain diseases by providing therapeutic genes to target cells. Administration of a gene therapy vector carrying the RPE65 gene in 12 patients with congenital blindness due to RPE65 mutations led to improvements in retinal and visual function and proved to be a safe and stable procedure. In a follow-up study, the same group of researchers led by Jean Bennett set out to discover whether it would be possible to safely administer the vector and the therapeutic transgene to the contralateral eye of the patients. A big concern was whether the first gene therapy injection might have primed the patients’ immune system to respond to the adeno-associated virus (AAV) vector or the product of the therapeutic transgene that it had delivered. To test the safety and efficacy of a second administration of gene therapy to the second eye, the authors demonstrated that readministration was both safe and effective in animal models. Then, they selected 3 of the original 12 patients and readministered the AAV vector and its RPE65 transgene to the contralateral eye. They assessed safety by evaluating inflammatory responses, immune reactions, and extraocular exposure to the AAV vector. Efficacy was assessed through qualitative and quantitative measures of retinal and visual function including the ability to read letters, the extent of side vision, light sensitivity, the pupillary light reflex, the ability to navigate in dim light, and evidence from neuroimaging studies of cortical activation (which demonstrated that signals from the retina were recognized by the brain). The researchers did not discover any safety concerns and did not identify harmful immune responses to the vector or the transgene product. Before and after comparisons of psychophysical data and cortical responses provided the authors with evidence that gene therapy readministration was effective and mediated improvements in retinal and visual function in the three patients. The researchers report that the lack of immune response and the robust safety profile in this readministration gene therapy study may be due in part to the immune-privileged nature of the eye, and the low dose and very pure preparation of the AAV vector. Demonstration of safe and stable reversal of blindness after a single unilateral subretinal injection of a recombinant adeno-associated virus (AAV) carrying the RPE65 gene (AAV2-hRPE65v2) prompted us to determine whether it was possible to obtain additional benefit through a second administration of the AAV vector to the contralateral eye. Readministration of vector to the second eye was carried out in three adults with Leber congenital amaurosis due to mutations in the RPE65 gene 1.7 to 3.3 years after they had received their initial subretinal injection of AAV2-hRPE65v2. Results (through 6 months) including evaluations of immune response, retinal and visual function testing, and functional magnetic resonance imaging indicate that readministration is both safe and efficacious after previous exposure to AAV2-hRPE65v2.

Constitutive and regulated expression of processed insulin following in vivo hepatic gene transfer.

To test whether hepatocytes engineered in vivo can serve as surrogate β cells by similarly secreting mature insulin in a glucose-sensitive manner, we prepared adenoviral vectors encoding wild-type proinsulin (hIns-wt), a modified proinsulin cleavable by the ubiquitously expressed protease furin (hIns-M3), or each of the two β cell specific pro-insulin convertases PC2 and PC3. Following a detailed in vitro characterization of the proteins produced by our vectors, we infected the liver and, for comparison, the muscle of a chemically induced murine model of type I diabetes. Insulin expression from the transduced tissues was extensively characterized and showed to be constitutive rather than regulated. To obtain regulated expression, we placed expression of hIns-M3 under the control of the dimerizer-inducible transcription system. Hormone secretion from mouse liver was negligible in the absence of the dimerizer drug rapamycin, was inducible in a dose-dependent manner upon its administration, and reversible following drug withdrawal. These data confirm liver as a promising target for in vivo expression of processed insulin. While suggesting that hepatocytes cannot provide authentic glucose-responsive regulation, these results demonstrate that pharmacological regulation is a promising alternative route to the controlled delivery of insulin following hepatic gene transfer.

Efficient trans-splicing in the retina expands the utility of adeno-associated virus as a vector for gene therapy

Recombinant vectors based on adeno-associated virus (AAV) can efficiently transduce many different cell types, including cells of the retina, resulting in stable gene expression. A major shortcoming of this vector is its small packaging capacity. A trans-splicing approach, which reconstitutes gene expression from two independent AAV vectors, can be used to overcome the vectors packaging limitations. The efficiency of this system to date has been disappointing, and therefore its utility for therapeutic application limited. We demonstrate here that efficiency and cellular specificity of trans-splicing is dependent on selection of the appropriate AAV serotype. Efficiency of transgene expression resulting from trans-splicing in skeletal muscle approaches that obtained when delivering the intact transgene when using AAV2 vectors packaged with AAV5 capsids (AAV2/5). This expands the potential of AAV vectors for retinal gene therapy. The use of AAV2/5 also increases the efficiency of trans-splicing in photoreceptors. Selection of the appropriate AAV serotype is likely to affect efficiency of trans-splicing in other organ systems as well.

Adenoviral vector-mediated insulin gene transfer in the mouse pancreas corrects streptozotocin-induced hyperglycemia.

Therapy for type 1 diabetes consists of tight blood glucose (BG) control to minimize complications. Current treatment relies on multiple insulin injections or an insulin pump placement, β-cell or whole pancreas transplantation. All approaches have significant limitations and have led to the realization that novel treatment strategies are needed. Pancreatic acinar cells have features that make them a good target for insulin gene transfer. They are not subject to autoimmune attack, a problem with pancreas or islets transplantation, they are avidly transduced by recombinant adenoviral vectors, and capable of exporting a variety of peptides into the portal circulation. Recombinant adenoviral vectors were engineered to express either wild-type or furin-modified human insulin cDNA (AdCMVhInsM). Immunodeficient mice were made diabetic with streptozotocin and injected intrapancreatically with the vectors. BG and blood insulin levels have normalized after administration of AdCMVhInsM. Immunohistochemistry and electron microscopy showed the presence of insulin in acinar cells throughout the pancreas and localization of insulin molecules to acinar cell vesicles. The data clearly establish a relationship between intrapancreatic vector administration, decreased BG and elevated blood insulin levels. The findings support the use of pancreatic acinar cells to express and secrete insulin into the blood stream. Gene Therapy (2001) 8, 1480–1489.

In vivo detection of gene expression in liver by 31P nuclear magnetic resonance spectroscopy employing creatine kinase as a marker gene

In vivo assessment of gene expression is desirable to obtain information on the extent and duration of transduction of tissue after gene delivery. We have developed an in vivo, potentially noninvasive, method for detecting virally mediated gene transfer to the liver. The method employs an adenoviral vector carrying the gene for the brain isozyme of murine creatine kinase (CK-B), an ATP-buffering enzyme expressed mainly in muscle and brain but absent from liver, kidney, and pancreas. Gene expression was monitored by 31P magnetic resonance spectroscopy (MRS) using the product of the CK enzymatic reaction, phosphocreatine, as an indicator of transfection. The vector was administered into nude mice by tail vein injection, and exogenous creatine was administered in the drinking water and by i.p. injection of 2% creatine solution before 31P MRS examination, which was performed on surgically exposed livers. A phosphocreatine resonance was detected in livers of mice injected with the vector and was absent from livers of control animals. CK expression was confirmed in the injected animals by Western blot analysis, enzymatic assays, and immunofluorescence measurements. We conclude that the syngeneic enzyme CK can be used as a marker gene for in vivo monitoring of gene expression after virally mediated gene transfer to the liver.

Pharmacologically regulated gene expression in the retina following transduction with viral vectors

The availability of inducible expression systems makes regulatable control of therapeutic proteins an attainable goal in gene therapy. We delivered tetracycline-inducible transgenes to the subretinal space using recombinant adenoviruses. Upon administration of doxycycline, we demonstrated reversible expression of green fluorescent protein in the retinal pigment epithelium as well as modulation of human growth hormone produced in the retina and secreted in the blood stream. This mode of delivery and regulation offers a unique way to evaluate gene function in the eye and represents a novel method for introducing therapeutic proteins into the retina.

Correction of hyperglycemia by adenoviral vector-mediated insulin gene expression in the murine pancreas

Introduction: Type I diabetes causes autoimmune destruction of b-cells in the islets of Langerhans. Current therapies consist of multiple insulin injections, pump, whole pancreas, or islet transplantation all of which have significant limitations. We hypothesized that the pancreatic acinar cell might be a good target for insulin gene transfer. Pancreatic acinar cells drain into the portal circulation, are not subject to immune attack, and are capable of exporting a variety of peptides.