Alpha Adrenergic Induction of Transport of Lysosomal Enzyme across the Blood-Brain Barrier.

The impermeability of the adult blood-brain barrier (BBB) to lysosomal enzymes impedes the ability to treat the central nervous system manifestations of lysosomal storage diseases. Here, we found that simultaneous stimulation of the alpha1 and alpha2 adrenoreceptor restores in adult mice the high rate of transport for the lysosomal enzyme P-GUS that is seen in neonates but lost with development. Beta adrenergics, other monoamines, and acetylcholine did not restore this transport. A high dose (500 microg/mouse) of clonidine, a strong alpha2 and weak alpha1 agonist, was able to act as monotherapy in the stimulation of P-GUS transport. Neither use of alpha1 plus alpha2 agonists nor the high dose clonidine disrupted the BBB to albumin. In situ brain perfusion and immunohistochemistry studies indicated that adrengerics act on transporters already at the luminal surface of brain endothelial cells. These results show that adrenergic stimulation, including monotherapy with clonidine, could be key for CNS enzyme replacement therapy.

High resolution crystal structure of human ß-glucuronidase reveals structural basis of lysosome targeting.

Human ß-glucuronidase (GUS) cleaves ß-D-glucuronic acid residues from the non-reducing termini of glycosaminoglycan and its deficiency leads to mucopolysaccharidosis type VII (MPSVII). Here we report a high resolution crystal structure of human GUS at 1.7 Å resolution and present an extensive analysis of the structural features, unifying recent findings in the field of lysosome targeting and glycosyl hydrolases. The structure revealed several new details including a new glycan chain at Asn272, in addition to that previously observed at Asn173, and coordination of the glycan chain at Asn173 with Lys197 of the lysosomal targeting motif which is essential for phosphotransferase recognition. Analysis of the high resolution structure not only provided new insights into the structural basis for lysosomal targeting but showed significant differences between human GUS, which is medically important in its own right, and E. coli GUS, which can be selectively inhibited in the human gut to prevent prodrug activation and is also widely used as a reporter gene by plant biologists. Despite these differences, both human and E. coli GUS share a high structure homology in all three domains with most of the glycosyl hydrolases, suggesting that they all evolved from a common ancestral gene.

Transgene produces massive overexpression of human beta -glucuronidase in mice, lysosomal storage of enzyme, and strain-dependent tumors.

beta-Glucuronidase (GUSB) is a lysosomal enzyme important in the normal step-wise degradation of glycosaminoglycans. Deficiency of GUSB causes the lysosomal storage disease mucopolysaccharidosis VII (MPS VII, Sly disease). Affected patients have widespread progressive accumulation of beta-glucuronide-containing glycosaminoglycans in lysosomes. Enzyme replacement, bone marrow transplantation, and gene therapy can correct lysosomal storage in the MPS VII mouse model. Gene therapy in MPS VII patients and animals may result in massive overexpression of GUSB in individual tissues, and the toxicity of such overexpression is incompletely investigated. To gain insight into the effect of massive overexpression of GUSB, we established 19 transgenic mouse lines, two of which expressed very high levels of human GUSB in many tissues. The founder overexpressing mice had from >100- to several thousand-fold increases in tissue and serum GUSB. The enzyme expression in most tissues decreased in subsequent generations in one line, and expression in liver and marrow fell in subsequent generations of the other. Both lines had morphologically similar widespread lysosomal storage of GUSB and secondary elevations of other lysosomal enzymes, a finding characteristic of lysosomal storage disease. One line developed tumors, and one did not. These transgenic models show that massive overexpression of a lysosomal enzyme can be associated with dramatic morphological alterations, which, at least in one of the two lines, had little clinical consequence. For the other transgenic line, the high frequency of tumor development in F(2) FVB progeny suggests that the vector used to generate the transgenic lines has an integration site-dependent potential to be oncogenic, at least in this strain background.