Noncoordinate expression of Drosophila glue genes: Sgs-4 is expressed at many stages and in two different tissues.

The glue genes of Drosophila melanogaster comprise a family of genes expressed at high levels in the salivary glands of late third instar larvae in response to the insect hormone ecdysone. We present evidence that, in contrast to the other glue genes, Sgs-4 is turned on throughout Drosophila development and is not expressed exclusively in the larval salivary glands. Larvae transformed with an Sgs-4/Adh (alcohol dehydrogenase) hybrid gene exhibit Sgs-4-directed Adh expression in the larval proventriculus as well as in the salivary glands as early as the first instar. Sgs-4-specific RNA can be detected at very low levels during all stages of development. During late third instar, levels of Sgs-4 RNA in the salivary glands increase several-thousand-fold, thereby accounting for the large amounts of Sgs-4 protein present in the glue produced by the salivary glands. This pattern of expression is unique to the Sgs-4 gene. While expression of several of the other glue genes can be detected in embryos and early larvae, they appear to be expressed neither throughout development nor in the larval proventriculus. Appearance of the glue gene RNAs in mid third instar salivary glands is noncoordinate, even for the chromosomally clustered genes Sgs-3, Sgs-7, and Sgs-8.     

Protein metabolism by the salivary glands and other organs of the larva of the blowfly, Calliphora erythrocephala

Protein metabolism in salivary glands, gut, haemolymph, and fat body during the last larval instar of the blowfly, Calliphora erythrocephala, has been investigated. In salivary glands, protein release, protein synthesis, amylase, and pepsin-like protease activity were maximal in 6 day larvae, this being at a time when the larvae had finished feeding. All these functions declined in glands from the rounded-off white puparial stage (R.O.) while acid phosphatase activity rose throughout the third instar to a maximum at the R.O. stage, Glands from 6 and 7 day larvae released protein which on disk gel electrophoresis separated into four minor bands and two major bands one of the latter possessing protease activity.In the gut, pepsin-like protease activity was maximal in 4 day larvae after which it fell rapidly thus following the feeding pattern of the larva in contrast to that in the salivary glands which did not.In vitro experiments showed that protease was released from 6 day glands through the basal membrane of the cells and not via the duct. A pepsin-like protease was also found in the haemolymph and fat body, the activity in the fat body rising rapidly during the latter part of the third instar, a rise which is attributed to the fat body sequestering protease from the haemolymph. Acid phosphatase activity in the fat body was maximal in 5 day larvae indicating that this enzyme was synthesized early in the third instar. It was shown that fat body sequestered ¹⁴C-labelled protein synthesized by and released from the salivary glands, most of the ¹⁴C activity being associated with a 600 g precipitable, acid-phosphatase rich fraction.It is proposed that in late third instar larvae the salivary glands function as glands of internal secretion, releasing protease into the haemolymph, which is then sequestered by the fat body (and perhaps other tissues) and is subsequently used in the lysis of the tissues at the time of metamorphosis.     

Cell differentiation during the ontogeny of larval salivary glands of the fly, Telmatoscopus albipunctatus

Using the larvae, pharate pupa, and pharate adults of the moth fly, Telmatoscopus albipunctatus, histological and ultrastructural features of the salivary glands were investigated. The gland lumen contains a milky secretion from the first instar. This secretion continues to ccur at all subsequent developmental stages; with the onset of the pharate pupal stage, however, the secretion becomes transparent and rather viscous. Histochemical tests revealed that it is mainly proteinaceous. Glands from the same developmental stage may respond differently to PAS-reaction.Various cell organelles were compared at consecutive stages of larval development and of secretory activity of the salivary glands. In first and second instar larvae autophagic vacuoles are virtually absent in the salivary gland cells. They were occasionally found in the third instar, when they appear to be engaged in the process of organelle turnover. Histolysis of the larval glands is initiated towards the close of the fourth instar when the number of autophagic vacuoles starts to increase. Simultaneously, the cytoplasm, previously full of ribosomes and endoplasmic reticulum, starts losing these structures. At the beginning of the pharate adult stage, the cytoplasm becomes practically devoid of all structures other than those engaged in autophagy.Polyteny of the chromosomes during ontogeny of the larval salivary glands is also discussed.     

The humoral immune response of sheep to antigens from larvae of the sheep blowfly (Lucilia cuprina)

The sheep blowfly, Lucilia cuprina, is a myiasis-causing insect whose larvae evoke an immune response in sheep. By means of an immuno-dot blot and Western immuno-blot assays it has been demonstrated that sheep experimentally infected with larvae produce antibodies against a wide array of components from all three larval instars, with each instar displaying a differing set of antigens. The electrophoretic profiles of the proteins in various larval extracts and the patterns of antibody reactivity were very different. Of the extracts tested (1st, 2nd and 3rd instar larval excretions/secretions and visceral homogenates, extracts of 3rd instar salivary glands, mid guts, haemolymph and cuticle) the most intense antibody reaction was detected against the salivary gland extract: preparations of larval excretions/secretions and from the larval mid gut also reacted strongly. In contrast a cuticle extract reacted minimally with infected sheep sera.     

Chew and spit: tree-feeding notodontid caterpillars anoint girdles with saliva

Caterpillars of the notodontid Oedemasia leptinoides (formerly Schizura) use their mandibles to cut shallow girdles that encircle the petioles and stems of tree hosts. When girdles are complete, the larvae bathe the girdle surface with fluid. We test whether the fluid originates from the labial salivary glands or ventral eversible gland by blocking the openings to the glands and observing whether fluid is still released onto the girdles. Only larvae with functional labial salivary glands anointed girdles with fluid. Analysis of girdle rinses for a prominent salivary enzyme, glucose oxidase, confirmed that larvae apply saliva and documented that application occurs primarily at the end of girdling. We propose that girdling by notodontids, together with related furrowing and leaf-clipping behaviors exhibited by diverse caterpillar groups, serve at least in part to introduce salivary components to exposed vascular tissues; these compounds presumably function to suppress plant defensive responses normally elicited by caterpillar feeding.     

Respiration of larval salivary glands of Drosophila in relation to the activity of specific genome loci

Oxygen consumption of intact larval salivary glands of Drosophila hydei was measured after the addition of intermediates of the citric acid cycle or amino acids to the incubation medium. The effect of these substances on respiration of glands previously submitted to anaerobiosis in vivo was compared with that of glands of control larvae. Only isocitrate and tyrosine stimulated respiration of anaerobically treated glands to a much higher extent than glands of control larvae. This stimulatory effect was abolished when RNA or protein synthesis was inhibited. It is suggested that some of the specific puffs occurring as a consequence of anaerobiosis reflect gene activity required for an increase in utilization of isocitrate and tyrosine for respiration under conditions of stress.     

Analysis of somatic and salivary gland antigens of third stage larvae of Rhinoestrus spp. (Diptera, Oestridae)

Larvae of Rhinoestrus spp. (Diptera, Oestridae) infect nasal and sinus cavities of horses, causing a nasal myiasis characterized by severe respiratory distress. Presently, the diagnosis of horse nasal botfly relies on the observation of clinical signs, on the post mortem retrieval of larvae or on molecular assays performed using pharyngeal swabs. The present study was carried out to characterize larval somatic proteins and salivary glands of Rhinoestrus spp. in a preliminary assessment towards the immunodiagnosis of equine rhinoestrosis. Out of the 212 necropsied horses 13 were positive for the presence of Rhinoestrus spp. larvae. The analysis of the sera from the infected animals by Western blotting assay showed the presence of a specific host humoral immune response against Rhinoestrus spp. larvae and proved that the salivary glands are the major immunogens in horse nasal botflies.     

Tissue antigens from the third instar larva of Drosophila melanogaster

Antibodies were prepared against the soluble proteins from six tissues of Drosophila larvae. These were used to analyse the antigens in different tissues and at different developmental stages. The results suggest (1) the pattern of antigens determines the characteristics of a tissue, (2) salivary gland antigens are sequestered by the imaginal disks, (3) not all pupal glue antigens are synthesized in the salivary glands, and (4) most larval serum antigens are synthesized by the fat body.     

Biochemical and ontogenetic aspects of glycoprotein synthesis in Drosophila virilis salivary glands

After SDS-polyacrylamide gel electrophoresis two glycosylated glue proteins are found in the salivary glands of Drosophila virilis late third instar larvae. Synthesis of larval glue protein 1 occurs in three successive steps: at first a precursor protein with a molecular weight of about 138,000 daltons is formed. This is modified by two subsequent steps of glycosylation, the first one involving hexosamine, the second one hexoses. Studies with tunicamycin and β-hydroxynorvaline suggest that glycosylation occurs at threonine residues. Larval glue protein 2 has a molecular weight of approximately 15,000 daltons and is weakly glycosylated. The synthesis of glue proteins is stage specific. It starts at about 120 hr after oviposition and attains its maximal rate about 20 hr later. At this time the larvae leave the food. Between ecdysone release and puparium formation (146–151 hr) larval glue protein synthesis is terminated. Throughout the prepupal stage a different set of glycoproteins is synthesized. Thus, the larval-prepupal transition is accompanied by the reprogramming of glycoprotein synthesis in salivary glands. The secretion products formed during the two developmental stages seem to possess different biological functions.     

Larval saliva in Drosophila melanogaster: production, composition, and relationship to chromosome puffs.

Drosophila melanogaster salivary glands produce a mucoprotein-containing saliva in the third larval instar. At the time of prepupa formation, the protein component of the saliva is more than 30% of the total gland protein. Electrophoresis of reduced and alkylated saliva proteins in acrylamide gels yields four saliva-specific fractions. Two protein fractions contain strongly linked sugar. The molecular weights of the proteins were ascertained in SDS-acrylamide gels. Molecular weights for two sugar-free fractions were found to be 12 × 10³ and 23 × 10³ and, for one fraction containing little sugar, it probably lies below 100 × 10³. The variability of saliva proteins in 67 wild types of D. melanogaster were investigated. With the help of transplantation experiments, it was shown that the salivary glands synthesize saliva autonomously. Saliva proteins could be electrophoretically demonstrated earliest in the salivary glands of 86- to 88-hr-old larvae. After saliva is discharged from the gland lumen at the beginning of prepupa formation, the glands produce another type of saliva during the entire prepupal stage and also secrete it into the gland lumen. The chromosome puffs in section 3C of the X chromosome and in section 68C in the third chromosome show a behavior that is positively correlated with larval saliva synthesis.     

麦蛾柔茧蜂幼虫唾液腺的显微与超微形态观察

本文采用解剖学观察、显微摄影、透射电镜等方法对麦蛾柔茧蜂Habrobracon hebetor幼虫唾液腺的显微形态、超微结构以及发育特性进行了观察和分析。麦蛾柔茧蜂幼虫唾液腺为一对无色透明至乳白色的管状腺体,自口腔沿中肠两侧向后延伸,单侧腺体在中部先分支、后合并成一不规则环状,端部呈单盲管状。唾液腺管道长度随幼虫龄期增加而呈线性增长。对唾液腺切片进行超微结构观察,发现腺管由两类差异明显的单层细胞组成,I型细胞微绒毛层较厚,胞内除有丰富的内质网和线粒体之外,还含有大量囊泡,并观察到囊泡运输分泌颗粒的现象;II型细胞微绒毛短,胞内的内质网和线粒体数量丰富。本文研究为深入探究寄生蜂幼虫的消化生理以及寄生蜂-寄主互作机制奠定了基础。     

Characteristics of the endocrine system in Drosophila melanogaster 1 (2)gl mutants, differing in time of death]

A comparative study of the state of the endocrine system and one of the larval organs, the salivary gland, has been carried out in larvae homozygous for the 1(2)gl gene. They differ in time of death (death at the third larval instar--larval allele, and at the prepupal state--prepupal allele). It is shown that homozygotes for the larval and prepupal allele have underdeveloped prothoracal glands. Corpora allata in homozygotes for the larval allele does not differ from the norm. Corpora allata in homozygotes for the prepupal allele is decreased proportionally to the decrease of prothoracal glands. A decrease of gland size is due to a decrease of the volume of cell but not to their number; this decrease is accompanied by the decrease of their relative DNA content. Salivary glands in homozygotes are reduced and comprise 80% of the normal size in homozygotes for the prepupal allele and 50% for homozygotes for the larval allele. Polyteny level in the salivary gland nuclei is much decreased as compared with the normal level. DNA level is more reduced in larvae homozygous for the larval allele.     

Cytoskeletal F-actin patterns in whole-mounted larval and adult salivary glands of the fleshfly, Sarcophaga bullata.

The patterns of filamentous actin were analysed in different larval, pupal and adult stages in the salivary glands of the fleshfly Sarcophaga bullata. Using the rhodamine labelled phalloidin staining method in combination with detergent extraction specific actin filament distribution was detected. The salivary glands which are histolysed during the process of metamorphosis show distinct cellular morphology and actin filament patterns in larvae and adults. The large third instar larval salivary gland cells contain a well developed apicolateral microvillar zone. In third instar larvae this microvillar zone invaginates and expands in the basal part of the lateral membranes. Larval salivary gland cells also contain numerous parallel basal actin bundles. The larval glands are histolysed during metamorphosis and adult glands are formed out of the imaginal cell group. At the onset of metamorphosis these basal actin bundles form a network of crossing bundles. The filamentous actin patterns of the proximal part of adult gland cells is confined to the apicolateral microvillar membranes. The cells in the distal, tubular part of the adult salivary glands show intense staining of their folded lateral membranes.     

Sequential gene activation by ecdysone in polytene chromosomes of Drosophila melanogaster. VI. Inhibition by juvenile hormones.

In the salivary gland chromosomes of late-third instar larvae and in late (8- to 12-hr) prepupae of Drosophila melanogaster, there are ecdysone-induced sequences of puffing patterns which can be reproduced in vitro. These two sequences are separated by a period when the glands are thought to be exposed to a low titer of β-ecdysone and during which they acquire the competence to respond to ecdysone at the late prepupal puff sites. Attempts to modify either the late larval or the late prepupal responses to ecdysone in vitro by the simultaneous addition of juvenile hormone (JH) with ecdysone, to larval or prepupal glands, respectively, are unsuccessful. If, however, JH (ca. 10^?6M) is added to larval glands cultured 6 hr in ecdysone and then 3 hr in JH alone, the subsequent induction of prepupal ecdysone puffs is inhibited. Thus the role of JH appears to lie in modifying the acquisition of competence to respond to ecdysone rather than in a direct antagonism between the two hormones.     

Selection and Evaluation of Tissue Specific Reference Genes in Lucilia sericata during an Immune Challenge

The larvae of the common green bottle fly Lucilia sericata (Diptera: Calliphoridae) have been used for centuries to promote wound healing, but the molecular basis of their antimicrobial, debridement and healing functions remains largely unknown. The analysis of differential gene expression in specific larval tissues before and after immune challenge could be used to identify key molecular factors, but the most sensitive and reproducible method qRT-PCR requires validated reference genes. We therefore selected 10 candidate reference genes encoding products from different functional classes (18S rRNA, 28S rRNA, actin, β-tubulin, RPS3, RPLP0, EF1α, PKA, GAPDH and GST1). Two widely applied algorithms (GeNorm and Normfinder) were used to analyze reference gene candidates in different larval tissues associated with secretion, digestion, and antimicrobial activity (midgut, hindgut, salivary glands, crop and fat body). The Gram-negative bacterium Pseudomonas aeruginosa was then used to boost the larval immune system and the stability of reference gene expression was tested in comparison to three immune genes (lucimycin, defensin-1 and attacin-2), which target different pathogen classes. We observed no differential expression of the antifungal peptide lucimycin, whereas the representative targeting Gram-positive bacteria (defensin-1) was upregulated in salivary glands, crop, nerve ganglion and reached its maximum in fat body (up to 300-fold). The strongest upregulation in all immune challenged tissues (over 50,000-fold induction in the fat body) was monitored for attacin-2, the representative targeting Gram-negative bacteria. Here we identified and validated a set of reference genes that allows the accurate normalization of gene expression in specific tissues of L. sericata after immune challenge.     

The Mitochondrial Genomes of Nuttalliella namaqua (Ixodoidea: Nuttalliellidae) and Argas africolumbae (Ixodoidae: Argasidae): Estimation of Divergence Dates for the Major Tick Lineages and Reconstruction of Ancestral Blood-Feeding Characters

Ixodida are composed of hard (Ixodidae), soft (Argasidae) and the monotypic Nuttalliellidae (Nuttalliella namaqua) tick families. Nuclear 18S rRNA analysis suggested that N. namaqua was the closest extant relative to the last common ancestral tick lineage. The mitochondrial genomes of N. namaqua and Argas africolumbae were determined using next generation sequencing and de novo assembly to investigate this further. The latter was included since previous estimates on the divergence times of argasids lacked data for this major genus. Mitochondrial gene order for both was identical to that of the Argasidae and Prostriata. Bayesian analysis of the COI, Cytb, ND1, ND2 and ND4 genes confirmed the monophyly of ticks, the basal position of N. namaqua to the other tick families and the accepted systematic relationships of the other tick genera. Molecular clock estimates were derived for the divergence of the major tick lineages and supported previous estimates on the origins of ticks in the Carboniferous. N. namaqua larvae fed successfully on lizards and mice in a prolonged manner similar to many argasids and all ixodids. Excess blood meal-derived water was secreted via the salivary glands, similar to ixodids. We propose that this prolonged larval feeding style eventually gave rise to the long feeding periods that typify the single larval, nymphal and adult stages of ixodid ticks and the associated secretion of water via the salivary glands. Ancestral reconstruction of characters involved in blood-feeding indicates that most of the characteristics unique to either hard or soft tick families were present in the ancestral tick lineage.     

Relationships between the parasitoid Hyposoter exiguae and Trichoplusia ni: Parasitoid-induced histo- and cytopathology

The histology and cytology of Trichoplusia ni larvae were studied for evidence of abnormality or pathology induced by the solitary ichneumonid endoparasitoid, Hyposoter exiguae. Sample control and parasitized larvae were fixed every other day, and sections of these larvae were stained with mercuric-bromophenol blue. The fat body of parasitized larvae failed to show many of the changes characteristic of normally developing controls and, on the last day of parasitism, revealed extensive pathological changes. Spermatogenesis continued normally until the end of the association in parasitized hosts even though their development was halted in the fifth larval stadium. Parasitoid larvae seemed to secrete a proteinaceous material from their salivary and rectal glands into the host hemocoel. This material may be responsible for the pathological changes reported here. The parasitoids apparently fed on hemolymph alone until about 24 hr before emergence and pupation.