Acute intermittent porphyria: vector optimization for gene therapy.

BACKGROUND

Acute intermittent porphyria (AIP) is an autosomal dominant disorder caused by the half-normal activity of hydroxymethylbilane synthase (HMB-synthase). Affected individuals can experience episodic, life-threatening, acute neurological attacks that are precipitated by various drugs, dieting, and hormonal changes. Intravenous hematin is used to treat the attacks, but a more effective, preventive therapy is needed, especially for patients with frequent attacks. Since the disease is a hepatic encephalopathy, efforts were focused towards evaluating four different combinations of liver-specific enhancers and promoters for maximal hepatic HMB-synthase expression.

METHODS

Four different mammalian expression vectors, each carrying a unique combination of liver-specific enhancers and promoters driving murine HMB-synthase cDNA expression, were transiently transfected into HepG2 cells. The vectors included: HMBS-1; human alpha1-microglobulin enhancer/alpha1-antityrpsin promoter (alpha1Me/alpha1ATp), HMBS-2; alpha1Me/human serum albumin promoter (alpha1Me/SAp), HMBS-3; human prothrombin enhancer/SAp (PTe/SAp), and HMBS-4; (PTe/alpha1ATp). Each HMB-synthase construct and a luciferase reporter construct were hydrodynamically coinjected into mice with HMB-synthase deficiency and evaluated for hepatic expression 24 h post-injection, the time-point of peak hepatic HMB-synthase expression.

RESULTS

Following transient transfection into HepG2 cells, HMBS-1 (alpha1Me/alpha1ATp) had the highest HMB-synthase expression level, with an approximately 8-fold increase over endogenous cellular activities. Construct HMBS-1 also had the highest hepatic HMB-synthase activity following hydrodynamic delivery into HMB-synthase deficient mice, with a approximately 6-fold increase over saline-treated mice.

CONCLUSIONS

These studies support the use of a gene therapy vector containing the alpha1Me/alpha1ATp combination for preclinical studies of the efficacy and safety of liver-targeted gene therapy for AIP.