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J. Biol. Chem., Vol. 266, Issue 28, 18502-18506, 10, 1991
BA Stanley and AE Pegg
Human S-adenosylmethionine (AdoMet) decarboxylase is synthesized as a
38-kDa proenzyme that is autocatalytically cleaved, forming the covalently
attached pyruvate cofactor and the two subunits (67 and 267 amino acid
residues) of the mature enzyme. Both the cleavage reaction and the
catalytic activity of the mature enzyme are stimulated by putrescine. Using
site-specific mutagenesis and in vitro transcription followed by
translation of the resultant RNA in a cellfree system, we have examined the
importance of several amino acid residues on the processing reaction rate
and catalytic activity and on stimulation of each of these by putrescine.
Changing Cys82 to Ala decreased the stimulatory effect of putrescine on
processing and completely eliminated catalytic activity, indicating a
probable role in the active site of the enzyme, whereas changing Cys49 or
Cys226 to Ala had minimal effects on processing and activity or the
putrescine stimulation of either. Since Cys49 is the only cysteine residue
in the smaller subunit, this indicates that disulfide-bond formation
between the two subunits cannot be necessary for maintenance of the
conformation for proenzyme processing or catalytic activity. Changing Glu8
or Glu11 to Gln produced an AdoMet decarboxylase that processed, but was
catalytically inactive. Mutation at Glu11 also completely eliminated the
putrescine stimulation of proenzyme processing, as did double mutation at
Glu8 and Glu11, whereas the single mutation at Glu8 had no effect on the
putrescine stimulation of proenzyme processing. Changing Glu15, Glu61,
Glu67, Glu247, or Glu247 and Glu249 to Gln had a minimal effect on
processing and activity or putrescine stimulation of either. These results
demonstrate a role for the smaller subunit in the catalytic activity of the
mature AdoMet decarboxylase enzyme and show that Glu8, Glu11, and Cys82 are
essential for catalytic activity, with Glu11 also being essential for the
putrescine stimulation of AdoMet decarboxylase proenzyme processing.
Amino acid residues necessary for putrescine stimulation of human S- adenosylmethionine decarboxylase proenzyme processing and catalytic activity
Department of Cellular and Molecular Physiology, Milton S. Hershey Medical Center, Pennsylvania State University College of Medicine, Hershey 17033.
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