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Title
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Carbonic anhydrase IV: purification of a secretory form of the recombinant human enzyme and identification of the positions and importance of its disulfide bonds.
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Authors
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A.Waheed,
T.Okuyama,
T.Heyduk,
W.S.Sly.
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Ref.
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Arch Biochem Biophys, 1996,
333,
432-438.
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PubMed id
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Abstract
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Chinese hamster ovary cells were stably transfected with the cDNA for human
carbonic anhydrase IV that was engineered to encode a secretory form of the
normally glycosylphosphatidylinositol-anchored membrane protein. Overexpression
was achieved by amplification of the cDNA and its dihydrofolate
reductase-containing expression vector by growth in the presence of
methotrexate. The 33-kDa secretory form of the enzyme was purified to
homogeneity from cellular secretions by inhibitor affinity chromatography.
Occasional CA IV preparations contained proteolytic fragments of 18 and 15 kDa
held together by disulfide bonds. N-terminal sequencing identified the 18-kDa
fragment as the N-terminus and the 15-kDa fragment as the C-terminal portion.
The specific activity of the purified enzyme preparations (2587 +/- 149 U/mg
protein) was comparable to that of enzyme purified from human tissues. In order
to identify the cysteines involved in the two disulfide bonds, enzyme purified
following metabolic labeling with [35S]cysteine was subjected to proteolytic
cleavage and the N-terminal amino acid sequence determined on the labeled
peptides isolated by HPLC. Results indicated that the disulfide bonds in the
native enzyme link Cys6 to Cys18 and Cys28 to Cys211. Reduction of the enzyme or
reduction followed by alkylation both destroy 70% of the enzyme activity and
make the enzyme susceptible to inactivation by denaturants. Furthermore, the
loss of activity of reduced enzyme on exposure to denaturants is not recovered
on removal of denaturants. By contrast, disulfide-bonded enzyme is not only more
resistant to inactivation by denaturants, but any loss of activity is reversed
on removal of denaturants. Fluorescence anisotropy measurements provided further
evidence that the disulfide-bonded enzyme retains structure in the presence of
denaturants. Taken together, these results show that the disulfide bonds
contribute significantly both to the retention of structure and of catalytic
activity in the presence of denaturants, and to the ability to renature
following removal of denaturants.
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