The vitellogenin of Leucophaea maderae: Synthesis as a large phosphorylated precursor

Abstract

Phosphorylation of vitellogenin (yolk protein precursor) and vitellin (major yolk protein) polypeptides of Leucophaea maderae was studied by [ 32P] ortho phosphate labeling and subsequent sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) autoradiography. The vitellogenin molecule was isolated from the hemolymph and fat body by antibody precipitation and high-performance liquid chromatography (HPLC), and shown to consist of at least five polypeptides (“subunits”) which had apparent molecular masses of 155, 112, 95, 92 and 54 kD. Labeling studies with 32P showed that the covalently attached phosphorus was distributed in an uneven fashion among the five polypeptides. The two heavily-phosphorylated polypeptides, 112 and 54 kD, corresponded to the large and small, mature vitellin subunits. Quantitative SDS-PAGE analysis of long-term 32P-labeled vitellin showed that these large and small “subunits” contained 55 and 30%, respectively, of the total radioactivity. When fat body was pulse-labeled with 32P we found a heavily-phosphorylated intracellular 215 kD polypeptide which was precipitable with anti-vitellogenin. The synthesis of this intracellular precursorform of vitellogenin (pre-Vg) was under absolute juvenile hormone control. In vitro 32P pulse-chase experiments showed that pre-Vg was proteolytically processed within the fat body into some (or possibly all) of the mature vitellogenin subnits. Furthermore, peptide mapping confirmed that all of the phosphorylated vitellogenin subunits were derived from pre-Vg. Since previous studies have shown that phosphoserine residues account for essentially all of the covalently-attached phosphorus of the native vitellogenin molecule, we speculate that the asymmetric pattern of vitellogenin and vitellin subunit-phosphorylation is due to an uneven distribution of phosphoserine residues along the initial pre-Vg polypeptide chain. Finally, we conclude that phosphorylation of vitellogenin occurred post-translationally in the fat body endoplasmic reticulum because we could identify 32P-labeled pre-Vg in purified microsomal vesicles but not in nascent vitellogenin polypeptide chains attached to vitellogenin polyribosomes.