Specific protection from phenocopy induction by heat shock

Mild heat treatments applied to whole animals or cell cultures of Drosophila prior to lethal heat shocks result in increased survival and protection against phenocopy induction. The optimal condition for the preliminary mild heat treatment is that which induces the synthesis of heat-shock proteins but does not turn off the protein synthesis that is in progress. Recovery of protein synthesis but not RNA synthesis following a drastic heat shock is much enhanced by the pretreatments. The results suggest that the protection for survival and against phenocopy induction is due to storage of messenger RNA.     

Drosophila salivary gland proteins and pupation

Pulse-labeling experiments of salivary glands from the prepupal stages of development showed selectively high rates of synthesis of a set of low molecular weight proteins (6K–12K). These proteins are stably maintained in the salivary glands during prepupal development and are subsequently transported to the pupation fluid (found between the pupal case and the prepupal cuticle) when pupation occurs. These small polypeptides are very basic with the major components having isoelectric points of 8.6–8.7 and the minor components having isoelectric points of 9.1–9.5. This study shows the continuing function of the salivary glands—specifically, the synthesis and secretion of a set of proteins with a putative role in pupation.     

The prepupal salivary glands of Drosophila melanogaster

Evidence is presented in support of the concept that the larval salivary gland of Drosophila melanogaster continues to function as an important secretory organ throughout prepupal stages and after pupation. Just after puparium formation, and at other later periods, the glands appear to be in the process of disintegration, but each time they recover until after pupation. Nuclear blebbing occurs through the time of survival of the glands, but is shown not to involve transport of RNA out of the nucleus. Transport in and out of the nucleus is clearly rapid and in a steady state as compared to the massive and intermittent export of cytoplasmic substance into the lumen of the gland.This work was supported by grants from the National Science Foundation (GB-23343, PCH-02044).     

Rapidly labeled proteins on the salivary gland chromosomes of Drosophila melanogaster

Experiments on short-term and pulse-chase labeling of chromosome proteins of the salivary glands of Drosophila melanogaster show unique patterns of label in the vicinity of chromosome puffs. A high turnover rate is indicated for these nonhistone proteins, which appear to form a fibrous sheath around the chromosomes. Acrylamide gel analyses of the chromosomal proteins that are quickly labeled, comparing compositions at different stages of development with compositions after heat shock, show that all are different and dependent on which chromosomal puffs are active and producing messenger RNA. The necessity for a continuous and rapid interchange of protein between the nucleus and cytoplasm is indicated, and it appears that regulation of gene activity must be related to this dynamic state of protein exchange. From the technical standpoint, it has been found that scanning electron microscopy (SEM) is especially useful for observing silver grains on opaque autoradiographs. It appears also that SEM will prove useful in a variety of studies of chromosome structure.