Amblyomma americanum: identification of tick salivary gland antigens from unfed and early feeding females with comparisons to Ixodes dammini and Dermacentor variabilis

Salivary gland antigens involved in host resistance to tick feeding by Amblyomma americanum (lone star tick) have been identified. Gland extracts from unfed and partially fed 12-, 48-, 72-, 96-, and 120-hr females and their corresponding midgut tissues were analyzed by immunoblotting with sera from naturally immune and hyperimmune sheep and rabbits. Polypeptides at 90, 75, 58, 45, 33, and 23 kDa from the salivary glands of A. americanum females were consistently observed with antibodies from both sheep and rabbits. No antigens unique to tick midgut tissue were detected with immune sera. Female Dermacentor variabilis and Ixodes dammini shared 90- and 45-kDa salivary gland antigens with A. americanum, and these may represent conserved polypeptides. We speculate that some of the salivary gland antigens represent components of tick cement, while others are playing some other yet undetermined role in tick feeding.     

Disposition and Orientation of Ductin (DCCD-Reactive Vacuolar H-ATPase Subunit) in Mammalian Membrane Complexes

The disposition and orientation of mouse ductin (the subunit c of the vacuolar H⁺-ATPase) in gap junctions has been examined. Like the Nephrops norvegicus (arthropod) form, mouse ductin in the intact junctional structure is resistant to high levels of nonspecific proteinase, suggesting that it is for the most part buried in the bilayer. Antisera to an octapeptide near the N-terminus cross-react with ductins in gap junction preparations from four different mouse tissues, from chicken and Xenopus laevis liver, and from N. norvegicus hepatopancreas. The antisera and antibodies, affinity purified against the octapeptide, agglutinate isolated gap junctions, suggesting that the N-terminus is located on the exposed surface, equivalent to the cytoplasmic face of an intercellular gap junction. The antibodies also block dye coupling when injected into cells in culture, confirming the cytoplasmic location of the epitope. The lipophylic reagent dicylohexyl carbodiimide (DCCD), which targets carboxyl groups within the membrane and selectively reacts with ductin in N. norvegicus gap junction preparations, rapidly inhibits junctional communication. Bafilomycin A₁, which inhibits V-ATPase and stops vacuolar acidification, does not affect dye coupling, showing that the inhibition seen with antibodies and DCCD is not an indirect consequence of their action on the ductin of V-ATPase. Consistent with this interpretation the anti-peptide antibodies do not bind to intact chromaffin granules or inhibit their V-ATPase activity, but do bind to osmotically disrupted granule membrane. This suggests that ductin has an orientation (N-terminus pointing away from the cytoplasm) in the vacuolar membrane opposite to that in the gap junction membrane.     

Ductin, a component of the V-ATPase, is developmentally regulated in Heliothis virescens midgut, and anti-ductin antibodies label lateral membranes

We previously cloned from Heliothis virescens a 16-kDa protein that is homologous to other ductin sequences. We also reported its immunolocalization with a specific affinity-purified anti-peptide antibody in the midgut and Malpighian tubule of feeding larvae, and concluded that the cloned proteolipid encodes the V-ATPase proton-transporting subunit c from the V₀ sector. We now present the immunolocalization of this protein in the midgut during the L₄-L₅ larval molt and early post-ecdysis into the fifth instar in H. virescens. The results show that the spatial expression of the 16-kDa protein is developmentally regulated. Labeling by anti-peptide antibody varies during the molt in the midgut goblet cell apical plasma membrane and the goblet cell apical valve. Epifluorescence and confocal microscopy revealed strong anti-ductin labeling in areas of cell-to-cell contact during the molt, and during early post-ecdysis into the fifth larval instar. The characteristic labeling pattern observed in areas of cell-to-cell contact is consistent with the claimed involvement of ductins in gap junctions. Conclusive evidence for the presence of the 16-kDa protein in areas of cell-to-cell contact in the midgut of feeding larvae is, however, lacking. V-ATPase regulation during the molt was also investigated by simultaneous immunohistochemistry with an anti-B subunit antiserum, a probe for the V₁ sector. Received: 2 April 1996 / Accepted: 14 November 1996     

Cell Junctions in Arthropod Ion-transport Systems

The epithelial cells involved in the movement of ions and waterform a major subset of all epithelial cell types. Both the formand the functions of cell junctions present in these cells areessentially the same as those found elsewhere. Gap junctionsare believed to regulate intercellular communication; desmosomesand hemidesmosomes provide mechanical anchorage to other cellsand the extracellular matrix; septate junctions play roles inproviding cell to cell anchorage, and perhaps in sealing thelateral surfaces of adjacent cells together to prevent paracellularfluid and solute movement; tight junctions (of limited distributionin insects) are seals between adjacent cells. They form a barrierto the paracellular movement of solutes and water. Examination of the junctions in salivary glands and midgut provideinsight into the roles of these junctions in the developmentand function of ion transport systems. In Manduca sexta (Johannsen)the cells of the salivary gland are joined by pleated septateand gap junctions. Individual salivary cells have numerous foldsand canaliculi. The walls of the canaliculi consist of extensivelyfolded plasma membrane in intimate association with mitochondria.Gap junctions connect adjacent parts of the same cell acrossmembrane folds, effectively shortening diffusion distances inthe cells. Hemidesmosomes are present in the walls of developingcanaliculi. They are attached to pore filaments that occupythe lumen of the developing canaliculi. The hemidesmosomes andpore filaments may have a morphogenetic role as they disappearafter the canaliculi are formed. In Manduca sexta the midgut cells are joined by gap and septatejunctions. These junctions differ in morphology from their counterpartsin the salivary gland; physiological studies show the gobletcells are not coupled to neighboring tall columnar cells. Wehave shown the gap junctions joining them are typical of non-couplingjunctions. Preliminary studies suggest that the gap junctionschange form when the cells are coupled.     

Na,K-ATPase and V-ATPase in ovarian follicles of Drosophila melanogaster.

Uncovering the cause and meaning of bioelectric phenomena in developing systems requires investigations of the distribution and activity of ion-transport mechanisms. In order to identify and localize ion pumps in ovarian follicles of Drosophila, we used immunofluorescence microscopy, immunoelectron microscopy, subcellular fractionation, immunoblots, and acridine-orange staining. We applied various antibodies directed against the Na,K-pump (Na,K-ATPase) and against vacuolar-type proton pumps (V-ATPase). During all phases of oogenesis, Na,K-ATPase were found in apical and lateral follicle-cell membranes and, during rapid follicle growth (beginning with stage 10), also in nurse-cell membranes and in the oolemma. V-ATPase were detected in various cytoplasmic vesicles and in yolk spheres and, beginning with stage 10, also in apical follicle-cell membranes and in the oolemma. Given these and earlier results, we propose that: 1) V-ATPase coupled to secondary active antiporters represent the ouabain-intensitive potassium pumps described previously; 2) both Na,K-ATPase and V-ATPase are involved in bioelectric phenomena as well as in osmoregulation and follicle growth, especially during stages 10-12; 3) organelle-associated V-ATPase play a role in vesicle acidification and in yolk processing; and 4) the channel-forming protein ductin is a component of both V-ATPase and gap junctions in ovarian follicles of Drosophila.     

Junctional types in the tissues of an onychophoran: the apparent lack of gap and tight junctions in Peripatus

The Onychophora are a rare group of primitive invertebrates, relatively little investigated. Tissues from a range of their digestive, secretory and excretory organs have been examined to establish the features of their intercellular junctions. Glutaraldehyde-fixed cells from the midgut and rectum, as well as the renal organ, mucous gland, salivary gland, epidermis, CNS and testis from specimens of Peripatus acacioi, have been studied by thin section and freeze-fracture electron microscopy. Adjacent cells in the epithelia of all these tissues are joined by apical zonulae adhaerentes, associated with a thick band of cytoskeletal fibrils. These are followed by regular intercellular junctional clefts, which, in thin sections, have the dense, relatively unstriated, appearance of smooth septate junctions (SSJ). However, freeze-fracture reveals that only the midgut has what appear to be characteristic SSJs with parallel alignments of closely-packed rows of intramembranous particles (IMPs); these IMPs are much lower in profile than is common in such junctions elsewhere. The mucous gland, testis, rectal and renal tissues exhibit, after freeze-fracture, the characteristic features of pleated septate junctions (PSJ) with undulating rows of aligned but separated junctional particles. Suggestions of tricellular septate junctions are found in replicas at the interfaces between 3 cells. In addition, renal tissues exhibit scalariform junctions in the basal regions of their cells. Between these basal scalariform and apical septate junctions, other junctions with reduced intercellular clefts are observed in these renal tissues as well as the rectum, but these appear not to be gap junctions. Such have not been unequivocally observed in any of the tissues studied from this primitive organism; the same is true of tight junctions.     

Developmental changes in midgut chromosomes of Drosophila gibberosa

In Drosophila gibberosa, differences between midgut and salivary gland chromosomes fall into two categories: tissue-specific band modulations which persist throughout the 90 h developmental period that we studied and tissue-specific puffs. Puffs that are common to both tissues tend to appear earlier in the midgut. Some major early ecdysteroid-induced puffs appear simultaneously in both tissues at the end of the third larval instar; however, the many late puffs that follow in the salivary glands are absent from the midgut. Intense puff activity in the early third larval instar midgut declines at the time of the hormonal pulse that initiates intense gene and secretory activity in salivary glands; the sloughing of midgut cells ensues.     

Relating proton pumps with gap junctions: colocalization of ductin,the channel-forming subunit c of V-ATPase,with subunit a and with innexins 2 and 3 during <Emphasis Type="Italic">Drosophila</Emphasis> oogenesis

Background

Ion-transport mechanisms and gap junctions are known to cooperate in creating bioelectric phenomena, like pH gradients, voltage gradients and ion fluxes within single cells, tissues, organs, and whole organisms. Such phenomena have been shown to play regulatory roles in a variety of developmental and regenerative processes. Using Drosophila oogenesis as a model system, we aim at characterizing in detail the mechanisms underlying bioelectric phenomena in order to reveal their regulatory functions. We, therefore, investigated the stage-specific distribution patterns of V-ATPase components in relation to gap-junction proteins.

Results

We analysed the localization of the V-ATPase components ductin (subunit c) and subunit a, and the gap-junction components innexins 2 and 3, especially in polar cells, border cells, stalk cells and centripetally migrating cells. These types of follicle cells had previously been shown to exhibit characteristic patterns of membrane channels as well as membrane potential and intracellular pH. Stage-specifically, ductin and subunit a were found either colocalized or separately enriched in different regions of soma and germ-line cells. While ductin was often more prominent in plasma membranes, subunit a was more prominent in cytoplasmic and nuclear vesicles. Particularly, ductin was enriched in polar cells, stalk cells, and nurse-cell membranes, whereas subunit a was enriched in the cytoplasm of border cells, columnar follicle cells and germ-line cells. Comparably, ductin and both innexins 2 and 3 were either colocalized or separately enriched in different cellular regions. While ductin often showed a continuous membrane distribution, the distribution of both innexins was mostly punctate. Particularly, ductin was enriched in polar cells and stalk cells, whereas innexin 2 was enriched in the oolemma, and innexin 3 in centripetally migrating follicle cells. In lateral follicle-cell membranes, the three proteins were found colocalized as well as separately concentrated in presumed gap-junction plaques.

Conclusions

Our results support the notion of a large variety of gap junctions existing in the Drosophila ovary. Moreover, since ductin is the channel-forming part of a proton pump and, like the innexins, is able to form junctional as well as non-junctional membrane channels, a plethora of cellular functions could be realized by using these proteins. The distribution and activity patterns of such membrane channels are expected to contribute to developmentally important bioelectric signals.

     

Plasmodium malariae: distribution of circumsporozoite protein in midgut oocysts and salivary gland sporozoites

The distribution of the circumsporozoite protein within developing Plasmodium malariae oocysts and salivary gland sporozoites was examined by immunoelectron microscopy using protein A-gold and a monoclonal antibody specific for the CS protein of P. malariae. Gold particles were found along the capsule of immature oocysts but rarely within the cytoplasm. Gold label was detected on the inner surface of peripheral vacuoles during oocyst maturation and the plasma membrane of the sporoblast. Salivary gland sporozoites and budding sporozoites in mature oocysts were labeled uniformly on the outer surface of their plasma membranes. The surface of sporozoites that ruptured into midgut epithelial cells were entirely covered with gold particles. No label was seen on the surface of sporozoites which ruptured into the midgut lumen. In addition, a rabbit polyclonal antibody against repeat a region of P. brasilianum CS protein reacted with P. malariae sporozoites.     

Identification and characterization of a new putative c-type lysozyme from malaria vector Anopheles stephensi

Lysozyme (E.C. 3.2.1.17) activity is reported from the malaria vector Anopheles stephensi. The activity was detected in the salivary gland and midgut using bacteriolytic radial diffusion assay. Spectrophotometric analysis indicated that higher level of lysozyme activity was maintained in both midgut and salivary gland tissues. The activity reached the highest level in 4-8 days old mosquitoes. Genomic PCR amplification revealed the presence of at least two putative lysozyme genes in the mosquito genome. Preliminary analysis of one of the 413 bp genomic fragments showed 56% identity to the lysozyme of mosquito A. gambiae. However, the nature and origin of the putative cloned lysozyme gene remains elusive.     

Heteromerization of innexin gap junction proteins regulates epithelial tissue organization in Drosophila

Gap junctions consist of clusters of intercellular channels, which enable direct cell-to-cell communication and adhesion in animals. Whereas deuterostomes, including all vertebrates, use members of the connexin and pannexin multiprotein families to assemble gap junction channels, protostomes such as Drosophila and Caenorhabditis elegans use members of the innexin protein family. The molecular composition of innexin-containing gap junctions and the functional significance of innexin oligomerization for development are largely unknown. Here, we report that heteromerization of Drosophila innexins 2 and 3 is crucial for epithelial organization and polarity of the embryonic epidermis. Both innexins colocalize in epithelial cell membranes. Innexin3 is mislocalized to the cytoplasm in innexin2 mutants and is recruited into ectopic expression domains defined by innexin2 misexpression. Conversely, RNA interference (RNAi) knockdown of innexin3 causes mislocalization of innexin2 and of DE-cadherin, causing cell polarity defects in the epidermis. Biochemical interaction studies, surface plasmon resonance analysis, transgenesis, and biochemical fractionation experiments demonstrate that both innexins interact via their C-terminal cytoplasmic domains during the assembly of heteromeric channels. Our data provide the first molecular and functional demonstration that innexin heteromerization occurs in vivo and reveal insight into a molecular mechanism by which innexins may oligomerize into heteromeric gap junction channels.     

Midgut antibodies reduce the reproductive capacity of Anopheles stephensi (Diptera: Culicidae)

Rabbits immunized with polypeptides of midgut of glucose fed A. stephensi resulted in high titer of antibodies (10(4)-10(6)) as detected by ELISA. Effect of antisera on fecundity, hatchability and engorgement was investigated. Fecundity was reduced drastically (62.4%). Eight polypeptides were recognized by the antisera raised against midgut tissues viz., 92, 85, 55, 52, 45, 38, 29 and 13 kDa. Cross reactivity of these antibodies with different tissues of A. stephensi as well as different species of Anopheles was also analyzed. The results indicated that anti-mosquito midgut antibodies had the potential to disrupt the reproductive physiology of mosquitoes in view of the present study, there is a need for further investigation with target antigens.     

A putative kinase-related protein (PKRP) from Plasmodium berghei mediates infection in the midgut and salivary glands of the mosquito

The completion of the Plasmodium (malaria) life cycle in the mosquito requires the parasite to traverse first the midgut and later the salivary gland epithelium. We have identified a putative kinase-related protein (PKRP) that is predicted to be an atypical protein kinase, which is conserved across many species of Plasmodium. The pkrp gene encodes a RNA of about 5300 nucleotides that is expressed as a 90 kDa protein in sporozoites. Targeted disruption of the pkrp gene in Plasmodium berghei, a rodent model of malaria, compromises the ability of parasites to infect different tissues within the mosquito host. Early infection of mosquito midgut is reduced by 58-71%, midgut oocyst production is reduced by 50-90% and those sporozoites that are produced are defective in their ability to invade mosquito salivary glands. Midgut sporozoites are not morphologically different from wild-type parasites by electron microscopy. Some sporozoites that emerged from oocysts were attached to the salivary glands but most were found circulating in the mosquito hemocoel. Our findings indicate that a signalling pathway involving PbPKRP regulates the level of Plasmodium infection in the mosquito midgut and salivary glands.     

Analysis of stage-specific and shared antigens derived from Rhipicephalus sanguineus by electrophoresis and Western blotting

e carried out an SDS-PAGE analysis of antigens of Rhipicephalus sanguineus using extracts of eggs (EE), larvae (LE), nymphs (NE), male salivary glands (MSGE), male midguts (MME), female salivary glands (FSGE) and female midguts (FME). Under non-reducing conditions a common band of about 205 kDa was observed. EE, LE and NE extracts showed groups of bands between 150 and 75 kDa. A protein pattern was observed in FSGE extract with a group of bands between 75 and 50 kDa and four bands between 15 and 6.5 kDa. In this case an apparently exclusive band of molecular weight about 25 kDa was observed. Under reducing conditions similarities between LE and NE extracts increased, separating from the EE pattern. On the other hand, we have determined the presence of stage-specific and common antigens on EE, LE, NE, MSGE, MME, FSGE and FME extracts of R.sanguineus by means of immunoblots using polyclonal sera of rabbits infested with larvae, nymphs or adults of this tick. EE extract was only recognized by the anti-larva sera. Higher reactivity was observed when the extracts were tested with anti-adult sera. In these experiments a very prominent band of molecular weight about 45 kDa was detected. This band was not observed under reducing conditions. Higher reactivity with anti-adult sera was observed against FSGE extract.     

Change of form of septate and gap junctions during development of the insect midgut

In insects, smooth septate junctions join cells derived from the embryonic midgut, and pleated septate junctions are found in all other tissues. Relatively little is known about either type of septate junction or the relationship between them, but they have been treated as two different junctions in the literature. The gap junctions which are associated with these septate junctions also differ. Crystalline gap junctions are found in the midgut, associated with smooth septate junctions, and irregular gap junctions are found in tissues where pleated septate junctions are located. We have examined the development of smooth septate junctions and crystalline gap junctions and the relationship between them, by studying the embryogenesis of the midgut in Manduca sexta (tobacco hornworm). At 56 hr of development (hatching is at 104 hr) pleated septate junctions and irregular gap junctions joined the midgut epithelial cells. At 65 hr, the septate junctions had disappeared, but gap junctions persisted. At 70 hr, smooth septate junctions had replaced the earlier pleated septate junctions and gap junctions associated with these smooth septate junctions were often of the crystalline form. In later embryos, the smooth septate junctions matured and enlarged, while all gap junctions became crystalline in form.     

Animal plasma membrane energization by proton-motive V-ATPases

Proton-translocating, vacuolar-type ATPases, well known energizers of eukaryotic, vacuolar membranes, now emerge as energizers of many plasma membranes. Just as Na⁺ gradients, imposed by Na⁺/K⁺ ATPases, energize basolateral plasma membranes of epithelia, so voltage gradients, imposed by H⁺ V-ATPases, energize apical plasma membranes. The energized membranes acidify or alkalinize compartments, absorb or secrete ions and fluids, and underwrite cellular homeostasis. V-ATPases acidify extracellular spaces of single cells such as phagocytes and osteoclasts and of polarized epithelia, such as vertebrate kidney and epididymis. They alkalinize extracellular spaces of lepidopteran midgut. V-ATPases energize fluid secretion by insect Malpighian tubules and fluid absorption by insect oocytes. They hyperpolarize external plasma membranes for Na⁺ uptake by amphibian skin and fish gills. Indeed, it is likely that ion uptake by osmotically active membranes of all fresh water organisms is energized by V-ATPases. Awareness of plasma membrane energization by V-ATPases provides new perspectives for basic science and presents new opportunities for medicine and agriculture. BioEssays 21:637–648, 1999. © 1999 John Wiley & Sons, Inc.     

Structural-membrane regulation of intercellular contacts of low-molecular weight peptides]

It has been shown by microelectrode techniques and microcytofluorometry that fragments of the substance P and L-vasopressin--low molecular physiologically active peptides of wide regulatory action--bind to the receptors on the surface of plasma membranes outside the region of high permeable gap contact in unimolar concentrations and cause an increase in the rate of intracellular diffusion exchange of inorganic ions and fluorescein molecules in the salivary gland cells of Drosophila larva. The growth of intracellular contact permeability induced by low peptide concentrations is blocked by carbodiimide--a reagent cross-linking the membrane proteins. On the basis of the previous data it is suggested that the functions of intracellular contacts are regulated by the distant action mechanism involving the generalized structural rearrangements of plasma membranes.     

Topological distribution of two connexin32 antigenic sites in intact and split rodent hepatocyte gap junctions

The membrane topology of connexin32, a principal polypeptide of gap junctions in diverse cell types, has been studied in rat and mouse hepatocyte gap junctions using site-specific antisera raised against synthetic oligopeptides corresponding to amino acid sequences deduced from cDNA clones. Based on published hydropathicity maps and identified protease-sensitive cleavage sites, oligopeptides were synthesized corresponding to two hydrophilic domains of connexin32, one predicted to face the cytoplasm, the other predicted to be directed extracellularly. Antisera were raised to keyhole limpet hemocyanin conjugates of the oligopeptides and used to map the distribution of their antigens using indirect immunocytochemistry on isolated gap junctions. The results directly demonstrated the cytoplasmic orientation of an antigen contained within amino acids 98-124 of the connexin32 sequence. The extracellular space in intact, isolated gap junctions is too small to permit binding of antibody molecules, necessitating the experimental separation of the junctional membranes to expose their extracellular surfaces using a urea/alkali procedure. While an antigen contained within amino acids 164-189 was visualized on the extracellular surfaces of some of the separated junctional membranes, variability in the observations and in the splitting procedure left ambiguities concerning the biological relevance of the observations after the denaturing conditions necessary to separate the junctional membranes. Using a different approach, however, the antigen could be exposed in intact liver using a hypertonic disaccharide junction-splitting procedure. The period of time of antigen exposure at the cell surface appears to peak at 30 s and disappear by 2-4 min. Taken together, these data demonstrate the extracellular orientation of an antigen contained within amino acids 164-189, which may be involved in cell-cell interaction within the gap junction.