Large sized nascent protein as dominating component during protein synthesis in Chironomus salivary glands

Cell-specific synthesis and glycosylation of secretory proteins in larval salivary glands of Chironomus thummi

Synthesis and glycosylation of larval salivary gland secretory proteins of Chironomus thummi were analyzed with respect to cell specific differences in the Balbiani ring (BR) pattern and glycoprotein composition of secretion formerly detected by histochemical staining procedures. In the secretion of a special cell type in salivary glands, which is characterized by the appearance of an additional BR, and additional polypeptide with a relative molecular weight (Mr) of 160 kD was found differing in its antigenic properties and tryptic fingerprint pattern from main cell secretion proteins. This so-called ssp-160 component is preferentially synthesized and glycosylated in the special cells. In the same cells, both the synthesis and glycosylation of all other major secretory proteins was found to be diminished or even repressed. In contrast to the conspicuous cell-specific differences at the level of protein synthesis. RNA analyses show the prominent synthesis of 75S RNA in both main and special cells and gave no clear indication of the synthesis of a smaller RNA fraction as expected from the size of ssp-160 component.--These and further data on synthesis and properties of secretory proteins as well as expression of BR DNA are discussed with regard to the assumption that at least some of the eight major secretory polypeptides are coded for by BR DNA. The BR gene(s) might have originated by manifold duplications and modifications of short repetitive prototype DNA sequences, which are coordinatively expressed.

Sequences translated by Balbiani ring 75S RNA in vitro are present in giant secretory protein from Chironomus tentans

The 75S RNA originating in the large Balbiani rings 1 and 2 (BRI and 2) was isolated and used for in vitro translation in the mRNA dependent reticulocyte lystate. Conditions (K+-concentration, temperature, time etc). were optimized for obtaining translation products of maximal size. Polypeptide chains up to about 500,000 D were obtained but no complete translation products. Trypic fingerprints were performed on the in vitro products as well as on the secretory protein components nos. I and II+III labelled with 35S-methionine. There was a large degree of correspondence between the fingerprint of the in vitro product and that of component I but less to that of component II+III. The results suggest that 75S RNA with an origin in the BR1 and BR2 codes for the giant secretory protein component I.