Browsing by Author "Arnson, Benjamin Donald"

Glycogen storage disease type Ia (GSD Ia) is an autosomal recessive metabolicdisorder caused deficiency of glucose-6-phosphatase (G6Pase) resulting from pathogenic variants in the G6PC gene. G6Pase catalyzes the hydrolysis of glucose-6-phosphate to release glucose which can then enter the bloodstream. GSD Ia patients have excess glycogen accumulation mainly in the liver and kidneys and suffer from life threatening hypoglycemia. The current treatment for GSD Ia is dietary therapy that requires patients to frequently consume uncooked cornstarch on a strict schedule. Cornstarch provides a complex carbohydrate that slowly releases glucose to prevent hypoglycemia. This treatment fails to prevent long-term complications associated with GSD Ia including renal failure and the development of hepatocellular adenomas and carcinomas. This lab and others have developed adeno-associated virus (AAV) vector based gene therapies to deliver and therapeutic G6PC transgene to affected tissues in GSD Ia animal models. However, the therapeutic effect is limited as AAV vector genomes are rapidly lost and the biochemical correction declines. Currently no treatment for GSD Ia exists that provides stable, robust expression of G6Pase that can clear glycogen and prevent hypoglycemia. This study employed a novel genome editing approach designed to insert the therapeutic G6PC into the endogenous locus in canine and murine models of GSD Ia. Integration of the transgene into the genome will promote stable expression of G6Pase and prevent the decline of vector genomes and the therapeutic benefit. This genome editing approach utilizes the CRISPR/Cas9 system to generated targeted double stranded DNA breaks at a targeted site in the genome. The G6PC transgene is present in a Donor template with homology to the DNA break to drive homology directed repair (HDR) resulting in the integration of the transgene into the genome. In a canine model of GSD Ia, editing and incorporation of the transgene was achieved in both adult dogs and puppies. Up to 1.0% of alleles were edited in the dog livers and contained the transgene. G6Pase production from the integrated transgene was detected, which correlated with prevention of hypoglycemia during fasting. This demonstrated genome editing in the liver of a large animal model for an inherited metabolic disorder using HDR to insert a therapeutic transgene. A subsequent study in GSD Ia mice also showed incorporation of a G6PC transgene in the mouse genome. Mice were treated with either the Donor transgene vector alone or with both the Donor and a CRISPR/Cas9 vector to assess to role of nuclease activity on integration. Mice treated with both vectors demonstrated improved blood glucose concentrations during fasting, decreased liver glycogen, and increased vector genome copies. Treatment with the pan PPAR agonist bezafibrate increased the efficiency of genome editing. Mice treated with bezafibrate that received both editing vectors had 5.9% of alleles that contained the integrated transgene, whereas only 3.1% of alleles contained the transgene in mice not treated with the drug. This work showed that integration of a therapeutic transgene using CRISPR/Cas9 based genome editing is possible in murine and canine models of GSD Ia. Editing resulted in biochemical correction and sustained transgene expression. These data support the further development of genome editing technologies for GSD Ia and other inherited metabolic disorders.