Abstract
The functions of the larval salivary glands (SGs) of Drosophila are traditionally associated with the production of a massive secretion during puparium formation; it is exocytosed into a centrally located lumen and subsequently expectorated via ducts, the pharynx and mouth. This so-called proteinaceous glue serves as an adhesive to attach the puparial case to a solid substrate. Great attention has been paid to the secretory cells of SGs, which are famous for their giant polytene chromosomes. However, substantially less attention has been devoted to individual or common ducts that form the most proximal portion of the SG organ via which the glue is released into the pharynx. In the present paper, we describe the organization and fine structure of the taenidia, highly specialized circumferential ring-like extracellular (cuticular) components on the internal side of these tubes. Two chitin-specific probes that have previously been used to recognize taenidia in Drosophila tracheae, Calcofluor White M2R (also known as Fluorescent Brightener 28) and the novel vital fluorescent dye SiR-COOH, show positively stained ductal taenidia in late larval SGs. As seen using scanning electron microscopy (SEM), the interior of the ductal tube contains regular and densely-arranged ridge-like circumferential rings which represent local thickenings of the cuticle in various geometries. The microtubular arrays that optically colocalize with taenidia in both the trachea and SG ducts are specifically and strongly recognized by fluorescently-conjugated colchicine as well as anti-tubulin antibody. In contrast to taenidia in the tracheae, the analogous structures in SG ducts cannot be detected by fluorescently-labeled phalloidin or even actin-GFP fusion protein, suggesting that the ducts lack a cortical network made of filamentous actin. We speculate that these taenidia may serve to reinforce the duct during the secretory processes that SGs undergo during late larval and late prepupal stages.
Highlights
The larval salivary glands (SGs) of Drosophila melanogaster represent a unique model organ
Upon a dramatic increase in the ecdysone titer a few hours prior to pupariation, the contents of the granules are released by exocytosis into the SG lumen, which is emptied by expectoration during puparium formation (Lane et al, 1972; von Gaudecker, 1972; Berendes & Ashburner, 1978; Farkaš & Šuťáková, 1998) where it serves as a glue to attach the puparial case to a solid substrate
The tubular duct is the last portion of the salivary gland system through which salivary glue secretion (Sgs)-glue must pass to reach the pharynx and mouth, where it is expectorated into the environment
Summary
The larval salivary glands (SGs) of Drosophila melanogaster represent a unique model organ. Upon a dramatic increase in the ecdysone titer a few hours prior to pupariation, the contents of the granules are released by exocytosis into the SG lumen, which is emptied by expectoration during puparium formation (Lane et al, 1972; von Gaudecker, 1972; Berendes & Ashburner, 1978; Farkaš & Šuťáková, 1998) where it serves as a glue to attach the puparial case to a solid substrate (e.g. vial glass wall). These granules constitute the components of the salivary glue secretion (Sgs). The Sgs represents a highly specialized and unique extracellular composite bioadhesive secretion, the individual protein components of which are encoded by a series of eight Sgs genes (Korge, 1975, 1977a, b; Ashburner & Berendes, 1978; Lehmann, 1996; Farkaš, 2016) that are known to form a set of so-called interecdysial chromosomal puffs
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