A. Bergfussman et al., HUMAN ACID BETA-GLUCOSIDASE - N-GLYCOSYLATION SITE OCCUPANCY AND THE EFFECT OF GLYCOSYLATION ON ENZYMATIC-ACTIVITY, The Journal of biological chemistry, 268(20), 1993, pp. 4861-4866
The five potential N-glycosylation sites (sequons) of human acid beta-
glucosidase were individually mutated to determine site occupancy and
the effect of site occupancy on selected catalytic and stability prope
rties of this enzyme. Each N-glycosylation consensus sequence [Asn-Xaa
-(Ser/Thr)] was obliterated by individually substituting glutamine (Q)
for asparagine (N). By expression of the normal and mutated cDNAs in
insect (Sf9) and COS-1 cells and subsequent immunoblotting with anti-h
uman acid beta-glucosidase antibodies, the four sequons at Asn-19, Asn
-59, Asn-146, and Asn-270 were shown to be glycosylated in either sour
ce. The sequon at Asn-462 was never occupied. The mutant enzymes N59Q,
N146Q, and N270Q were catalytically active and had normal interaction
s with active site-directed inhibitors as well as with the activators,
phosphatidylserine and saposin C. Of the occupied sequons, N-glycosyl
ation of the first was critical to the synthesis of a catalytically ac
tive enzyme. Alteration of this sequon, Asn-19-Ala-20-Thr-21, by the s
ubstitutions N19Q, N19D, N19E, or T21G led to a lack of glycosylation
at this site. Enzymes containing N19Q, N19E, or T21G had significant d
ecreases (3- to 60-fold) in intrinsic enzyme activity. The N19D enzyme
had nearly normal catalytic activity and had enhanced activation by p
hosphatidylserine. These results show that sequon occupancy as well as
steric effects at residue 19 are important for the development of an
active conformer of this enzyme. This is the first example of a lysoso
mal hydrolase that requires sequon occupancy for the synthesis of a ca
talytically active