A Novel Approach for Enzyme Replacement Therapy

Metabolic diseases arise from mutations in key enzymes of major metabolic pathways. One promising approach for the treatment of such diseases is based on the administration of a wild-type enzyme to substitute the activity of the impaired enzyme by the use of enzyme replacement therapy, yet it is important to deliver this enzyme to the specific deficient tissue. We suggest a new concept for the treatment of metabolic diseases using fusion proteins. We examined the feasibility of this concept in the well characterized metabolic disease, phenylketonuria (PKU), which results from a mutation in the liver enzyme phenylalanine hydroxylase (PAH). PAH is a key enzyme in the metabolic pathway of phenylalanine. Deficiency in PAH leads to high and persistent levels of this amino acid in the plasma of PKU patients, causing permanent neurological damage. Currently a low protein diet is still considered the only effective treatment for most PKU patients. To restore PAH activity in the liver of PKU patients, we constructed PAH-based fusion proteins with delivery moieties based on the HIV-transactivator of transcription peptide, and fragments of human hepatocyte growth factor aiming to specifically target PAH to the liver. We show that these new fusion proteins can be delivered into a variety of human liver cell lines and retain PAH activity after being internalized. We also show that plasma phenylalanine levels were dramatically lowered in mice treated with PAH-based fusion proteins after intravenous administration. We therefore suggest an alternative concept for the treatment of PKU using targeted fusion proteins, which may also be applied to the treatment of other metabolic diseases.