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(Received for publication, October 23, 1995) Gene fusions encoding the membrane anchor region of yeast
Volume 271,
Number 7,
Issue of February 16, 1996 pp. 3398-3405
©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
1,4-Galactosyltransferase) in Yeast
1,2-mannosyltransferase (Mnt1p) fused to human
1,4-galactosyltransferase (Gal-Tf) were constructed and expressed
in the yeast Saccharomyces cerevisiae. Fusion proteins
containing 82 or only 36 N-terminal residues of Mnt1p were produced and
quantitatively N-glycosylated; glycosyl chains were shown to
contain 1,6-, but not 1,3-mannose determinants, a structure
typical for an early Golgi compartment. A final Golgi localization of
both fusions was confirmed by sucrose gradient fractionations, in which
Gal-Tf activity cofractionated with Golgi Mnt1p activity, as well as by
immunocytological localization experiments using a monoclonal
anti-Gal-Tf antibody. In an in vitro Gal-Tf enzymatic assay
the Mnt1/Gal-Tf fusion and soluble human Gal-Tf had comparable K values for UDP-Gal (about 45
µM). To demonstrate in vivo activity of the
Mnt1/Gal-Tf fusion the encoding plasmids were transformed in an alg1 mutant, which at the non-permissive temperature transfers
short (GlcNAc)
glycosyl chains to proteins. Using specific
lectins the addition of galactose to several yeast proteins in
transformants could be detected. These results demonstrate that Gal-Tf,
a mammalian glycosyltransferase, is functional in the molecular
environment of the yeast Golgi, indicating conservation between yeast
and human cells. The in vivo function of human Gal-Tf
indicates that the yeast Golgi is accessible for UDP-Gal and suggests
strategies for the construction of yeast strains, in which desired
glycoforms of heterologous proteins are produced.
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