THE ENZYMATIC IODINATION OF THE RED CELL MEMBRANE

doi:10.1083/jcb.55.2.390

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ARTICLE

THE ENZYMATIC IODINATION OF THE RED CELL MEMBRANE

Ann L. Hubbard ¹ and Zanvil A. Cohn ¹

¹ From The Rockefeller University, New York 10021

An enzymatic iodination procedure utilizing lactoperoxidase(LPO), radioactive iodide, and hydrogen peroxide generated bya glucose oxidase-glucose system has been described and utilizedfor a study of the red cell membrane. 97% of the incorporatedisotope is in the erythrocyte ghost and 3% is associated withhemoglobin. No significant labeling of the red cell membraneoccurs in the absence of LPO or by the deletion of any of theother reagents. A 6 million-fold excess of chloride ions inhibitsiodination by no more than 50%. Incorporation of up to 1 x 10⁶iodide atoms into a single erythrocyte membrane results in nosignificant cell lysis. The incorporated label is exclusivelyin tyrosine residues as monoiodotyrosine. 10–15% of thetrichloroacetic acid-precipitable radioactivity can be extractedwith lipid solvents but is present as either labeled proteinor ¹²⁵I. Sodium dodecyl sulfate-polyacrylamide gel electrophoresisof solubilized membrane proteins reveals only two labeled proteinbands out of the 15 present, and the presence of 50-1 x 10⁶iodide atoms per ghost does not alter this pattern. Componenta has a molecular weight of 110,000, is carbohydrate poor, andrepresents 40% of the total label. Component b has an apparentmolecular weight of 74,000, contains all of the demonstrablesialic acid, and accounts for 60% of the total label. Trypsinizationof iodinated, intact red cells results in the disappearanceof only component b, the appearance of labeled glycopeptidesin the medium, and the absence of smaller, labeled peptidesremaining in the membrane. Pronase treatment hydrolyzes componentb in a similar fashion, but also cleaves component a to a 72,000mol wt peptide which is retained in the membrane. A combinationof protease treatment and double labeling with ¹²⁵I and ¹³¹Idoes not reveal the appearance of previously unexposed proteins.

Submitted on April 21, 1972
Revised on June 2, 1972

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