Differentiation of the stable hyaline cells in response to foreign particles injections into the larvae of blowfly calliphora vomitoria

Injection of foreign particles (charcoal and human erythrocytes) into the larvae of Calliphora vomitoria provokes the complex immune response including their phagocytosis, nodulation and encapsulation by plasmatocytes and thrombocytoids. Precursors of thrombocytoids and analogs of Drosophila lamellocytes are very frequent during the periods of feeding and crop emptying, but fully disappear in wandering larvae. Injection of charcoal or erythrocytes into crop emptying larvae leads also to a dramatic increase in the number of stable hyaline cells, precursors of thrombocytoids. The hyaline cells differentiate from prohaemocytes and, quite possibly, from young weakly-specialized plasmatocytes in a day after injection. Later they are transformed to prothrombocytoids and thrombocytoids. The number of hyaline cells and young plasmatocytes in the crop emptying larvae of C. vomitoria is far greater than that in the same age larvae of C. vicina. Presumably it accounts for significantly increasing rate of stable hyaline cells differentiation in the injected larvae of C. vomitoria. Their part after injection of charcoal particles or erythrocytes may reach 40-50 % of the main haemocyte number compared to 20-25% in C. vicina. After completion of the crop emptying, the rate of hyaline cells differentiation in response to the foreign particles injection is evidently reduced but remains to be distinctly visible. Injections of saline also stimulate the differentiation of the stable hyaline cells from prohaemocytes but elevation of their amount is more weak and gradual. The bacterial immunization and needle prick show no effect. The treatments, inducing the rising of hyaline cells differentiation, lead also to pupariation delay. This correlation suggests involvement of the endocrine system into this process.     

Programmed cell death in salivary glands of Drosophila arizonae and Drosophila mulleri

Programmed cell death (PCD) in insect metamorphosis assumes a great diversity of morphology and controlling processes that are still not well understood. With the objective of obtaining information about the PCD process, salivary glands of Drosophila arizonae and D. mulleri were studied during larval-pupal development. From the results, it can be concluded that the type of the PCD that occurs in these organs is morphologically typical of apoptosis (formation of apoptotic nuclei, followed by fragmentation into apoptotic bodies). Histolysis happens in both species, between 22 and 23 h after pupation. There were no significant differences between the species studied. Apoptosis does not occur simultaneously in all cells. Cytoplasmic acid phosphatase activity gradually increases during development, suggesting the existence of acid phosphatases that are only expressed during the apoptotic stage. Twenty hours after pupation, salivary glands already show biochemical alterations relative to nuclear permeability such as acidification, possibly due to the fusion of lysosomes with the nucleus a few hours before apoptosis. Autophagy seems to act together with apoptosis and has a secondary role in cell death.     

Leucokinin and callitachykinin immunoreactive neurons during postembryonic development of calliphora vomitoria (L.) (DIPTERA : CALLIPHORIDAE)

Neurons containing 2 types of myotropic neuropeptides were investigated by immunocytochemistry during postembryonic development of the brain and ventral nerve cord of the blowfly Calliphora vomitoria (Diptera : Calliphoridae). Antisera raised against the insect neuropeptides Callitachykinin II (CavTK II), Locustatachykinin I (LomTK I), and Leucokinin I (LK I) were used. Callitachykinin immunoreactive (CavTK–IR) neurons were detected from the 1st-instar larva throughout development to adult. The number of CavTK–IR cell bodies in the brain was 4–16 in larval stages, 10–84 in pupal stages, and over 140 neurons in the newly emerged fly. With the CavTK antiserum, the fibers of only 4 descending neurons were detected in thoracico–abdominal ganglia throughout development. The antiserum to LomTK displayed the same neurons as that to CavTK II as well as a small number of additional neurons. Notably, there were seen about 14–20 locustatachykinin-like immunoreactive (LomTK-LI) cell bodies in the thoracico–abdominal ganglia throughout development. Leucokinin-like immunoreactive (LK-LI) neurons were labeled throughout postembryonic development. In the brain, 2–4 LK-LI cell bodies were labeled from 1st-instar larva to 8-day-old pupa, and 6 LK-LI cell bodies were labeled in the adult brain. In the abdominal ganglia, 7 pairs of LK-LI cell bodies were labeled from 1st-instar larva to 96-h-old pupa, 8 pairs in 8-day-old pupa, and 9 pairs in newly emerged fly, respectively. The CavTK containing neurons in the brain displayed a drastic increase in numbers from larval stages to adult, which indicates an addition of functional roles for this type of peptide. During earlier pupal stages, the number of CavTK–IR neurons decreased. The LK-LI neurons, however, were strongly immunoreactive throughout postembryonic development. Only one additional pair of cells appeared in the brain and 2 additional pair of cells appeared in the abdominal ganglia of the adult as compared with larvae. The continuous high expression of LK-LI material may suggest a functional role for this type of peptide during development.     

Connexins in salivary glands

Connexins (Cxs) make up a family of gap junction structural proteins that form hexameric assemblies in the plasma membranes of adjacent cells that interact to form intercellular channels. It has been demonstrated that many kinds of CXs are differentially expressed in a variety of tissues; however, there have been only a few studies of CX expression in rat salivary glands. The co-localization of CX26 and 32 was examined in the parotid glands. Double immunofluorescence revealed that CX26 and 32 were present in the same gap junction. Double immuno-electron microscopy showed co-localization of both CX26 and 32 on the same gap junctional membranes between acinar cells. These results suggest that CX26 and 32 may participate in regulation of secretory function and permeability of acinar cells in the rat parotid glands.     

Rearrangement of the tubulin and actin cytoskeleton during programmed cell death in Drosophila salivary glands

During larva-to-pupa metamorphosis Drosophila salivary glands undergo programmed cell death by autophagocytosis. Although ultrastructure of Drosophila salivary glands has been extensively studied in the past, little is known about mechanism of programmed cell death, especially the role of the cytoskeleton. In this paper we describe changes in microtubule and actin filament network compared to the progress of DNA fragmentation and redistribution of acid phosphatase. In feeding and wandering larvae microtubules and actin filaments form regular networks localized mostly along the plasma membrane. The first major rearrangement of microtubules and actin filaments occurred when larvae everted spiracles and the glands shifted their secretion from saliva to mucoprotein glue (stage L1). Microtubule cytoskeleton became denser and actin filaments concentrated along cell boundaries. At the same time nuclei flattened and migrated into the microtubule-rich layer near the basal membrane. In late prepupae (8-10 h after P1) the microtubule network became fainter, and actin filaments appeared frequently deeper in cytoplasm, gradually concentrating around nuclei. Simultaneously large patches of acid phosphatase activity surrounded nuclei and shortly thereafter chromosomal DNA began to fragment. During the final collapse of the gland (early pupae, 13.5 h after formation of white puparium) cellular fragments and autophagic vacuoles contained a continuous F-actin lining and the microtubule network displayed signs of extensive degradation. The results are consistent with the hypothesis that, in Drosophila salivary glands, extensive autophagic activities target nuclei for degradation; that this process occurs late in the course of programmed cell death; and that it directly involves cytoskeletal structures which are altered far earlier during the course of cell death.     

Characteristics of sialidase in the rat salivary glands

Using 4-methylumbelliferyl-N-acetylneuraminic acid (4MU-NeuAc) as substrate, we measured sialidase activity in the salivary glands and other organs of the rat. The pH optima of salivary gland sialidase were between 4.0 and 4.5, which were similar to those of the enzyme in the brain, liver and kidney. Among the salivary glands, the submandibular one showed the highest sialidase activity followed by the parotid and the sublingual glands. However, sialidase activity in these glands was lower when compared with the activity in the brain, liver and kidney. From the subcellular distribution study, salivary gland sialidase was found to be mainly localized in the lysosomes. The pH optima of the lysosomal sialidase of the salivary glands were between 4.0 and 4.5; and Km values for 4MU-NeuAc approximately 0.09 mmol/l. In the submandibular and parotid glands, a soluble sialidase with a different pH optimum (5.5) and Km value (0.25 mmol/l) was also detected.     

Immunocytochemistry of myoepithelial cells in the salivary glands

MECs are distributed on the basal aspect of the intercalated duct and acinus of human and rat salivary glands. However, they do not occur in the acinus of rat parotid glands, and sometimes occur in the striated duct of human salivary glands. MECs, as the name implies, have structural features of both epithelial and smooth muscle cells. They contract by autonomic nervous stimulation, and are thought to assist the secretion by compressing and/or reinforcing the underlying parenchyma. MECs can be best observed by immunocytochemistry. There are three types of immunocytochemical markers of MECs in salivary glands. The first type includes smooth muscle protein markers such as -SMA, SMMHC, h-caldesmon and basic calponin, and these are expressed by MECs and the mesenchymal vasculature. The second type is expressed by MECs and the duct cells and includes keratins 14, 5 and 17, 1β1 integrin, and metallothionein. Vimentin is the third type and, in addition to MECs, is expressed by the mesenchymal cells and some duct cells. The same three types of markers are used for studying the developing gland.

Development of MECs starts after the establishment of an extensively branched system of cellular cords each of which terminates as a spherical cell mass, a terminal bud. The pluripotent stem cell generates the acinar progenitor in the terminal bud and the ductal progenitor in the cellular cord. The acinar progenitor differentiates into MECs, acinar cells and intercalated duct cells, whereas the ductal progenitor differentiates into the striated and excretory duct cells. Both in the terminal bud and in the cellular cord, the immediate precursors of all types of the epithelial cells appear to express vimentin. The first identifiable MECs are seen at the periphery of the terminal bud or the immature acinus (the direct progeny of the terminal bud) as somewhat flattened cells with a single cilium projecting toward them. They express vimentin and later -SMA and basic calponin. At the next developmental stage, MECs acquire cytoplasmic microfilaments and plasmalemmal caveolae but not as much as in the mature cell. They express SMMHC and, inconsistently, K14. This protein is consistently expressed in the mature cell. K14 is expressed by duct cells, and vimentin is expressed by both mesenchymal and epithelial cells.

After development, the acinar progenitor and the ductal progenitor appear to reside in the acinus/intercalated duct and the larger ducts, respectively, and to contribute to the tissue homeostasis. Under unusual conditions such as massive parenchymal destruction, the acinar progenitor contributes to the maintenance of the larger ducts that result in the occurrence of striated ducts with MECs. The acinar progenitor is the origin of salivary gland tumors containing MECs. MECs in salivary gland tumors are best identified by immunocytochemistry for -SMA. There are significant numbers of cells related to luminal tumor cells in the non-luminal tumor cells that have been believed to be neoplastic MECs.     

Adrenergic innervation of the salivary glands in the rat

Summary The adrenergic innervation of the major salivary glands in the rat has been studied by a specific histochemical method for the visualization of the adrenergic transmitter. Adrenergic varicose nerve fibres were found, located in a typical adrenergic ground plexus closely surrounding the serous acini of the submaxillary and parotid glands, but not the acini of the mainly mucous sublingual gland. The ducts were found to be completely devoid of adrenergic innervation. Arterioles and venules in the stroma of all three glands and certain very small vessels, possibly the sphincters of arterio-venous anastomoses, were also richly innervated by adrenergic vasomotor fibres. The relationship of the adrenergic nerve fibres to the different functional units of the gland parenchyma is discussed.The investigation has been supported by a research grant (B 66–257) from the Swedish Medical Research Council and by a Public Health Service Research Grant (NB 05236-01) from the National Institute of Neurological Diseases and Blindness.     

Channels and transporters in salivary glands

According to the two-stage hypothesis, primary saliva, a NaCl-rich plasma-like isotonic fluid is secreted by salivary acinar cells and its ionic composition becomes modified in the duct sytem. The ducts secrete K⁺ and HCO₃^- and reabsorb Na⁺ and Cl^- without any water movement, thus establishing a hypotonic final saliva. Salivary secretion depends on the coordinated action of several channels and transporters localized in the apical and basolateral membrane of acinar and duct cells. Early functional studies in perfused glands, followed by the molecular cloning of several transport proteins and the subsequent analysis of mutant mice, have greatly contributed to our understanding of salivary fluid and the electrolyte secretion process. With a few exceptions, most of the key channels and transporters involved in salivary secretion have now been identified and characterized. However, the picture that has emerged from all these studies is one of a complex molecular network characterized by redundancy for several transport proteins, compensatory mechanisms, and adaptive changes in health and disease. Current research is directed to the molecular interactions between the determinants and the ways in which they are regulated by extracellular signals and intracellular mediators. This review focuses on the functionally and molecularly best-characterized channels and transporters that are considered to be involved in transepithelial fluid and electrolyte transport in salivary glands.