Transgene‐mediated suppression of dengue viruses in the salivary glands of the yellow fever mosquito,Aedes aegypti

Controlled sex‐, stage‐ and tissue‐specific expression of antipathogen effector molecules is important for genetic engineering strategies to control mosquito‐borne diseases. Adult female salivary glands are involved in pathogen transmission to human hosts and are target sites for expression of antipathogen effector molecules. The Aedes aegypti 30K a and 30K b genes are expressed exclusively in adult female salivary glands and are transcribed divergently from start sites separated by 263 nucleotides. The intergenic, 5′‐ and 3′‐end untranslated regions of both genes are sufficient to express simultaneously two different transgene products in the distal‐lateral lobes of the female salivary glands. An antidengue effector gene, membranes no protein (Mnp), driven by the 30K b promoter, expresses an inverted‐repeat RNA with sequences derived from the premembrane protein‐encoding region of the dengue virus serotype 2 genome and reduces significantly the prevalence and mean intensities of viral infection in mosquito salivary glands and saliva.     

Reduction of malaria transmission by transgenic mosquitoes expressing an antisporozoite antibody in their salivary glands

We have previously developed a robust salivary gland‐specific expression system in transgenic Anopheles stephensi mosquitoes. To establish transgenic mosquito lines refractory to Plasmodium falciparum using this system, we generated a transgenic mosquito harbouring the gene encoding an anti‐P. falciparum circumsporozoite protein (PfCSP) single‐chain antibody (scFv) fused to DsRed in a secretory form (mDsRed‐2A10 scFv). Fluorescence microscopy showed that the mDsRed‐2A10 scFv was localized in the secretory cavities and ducts of the salivary glands in a secreted form. To evaluate P. falciparum transmission‐blocking in a rodent malaria model, a transgenic Plasmodium berghei line expressing PfCSP in place of PbCSP (PfCSP/Pb) was constructed. The PfCSP/Pb parasites were able to bind to the mDsRed‐2A10 scFv in the salivary glands of the transgenic mosquitoes. Importantly, the infectivity of the transgenic mosquitoes to mice was strongly impaired, indicating that the parasites had been inactivated. These results suggest that salivary gland‐specific expression of antisporozoite molecules could be a promising strategy for blocking malaria transmission to humans.     

Positive selection drives accelerated evolution of mosquito salivary genes associated with blood‐feeding

The saliva of bloodsucking animals contains dozens to hundreds of proteins that counteract their hosts’ haemostasis, inflammation and immunity. It was previously observed that salivary proteins involved in haematophagy are much more divergent in their primary sequence than those of housekeeping function, when comparisons were made between closely related organisms. While this pattern of evolution could result from relaxed selection or drift, it could alternatively be the result of positive selection driven by the intense pressure of the host immune system. We investigated the polymorphism of five different genes associated with blood‐feeding in the mosquito Anopheles gambiae and obtained evidence in four genes for sites with signatures of positive selection. These results add salivary gland genes from bloodsucking arthropods to the small list of genes driven by positive selection.     

GP35 ANOAL, an abundant acidic glycoprotein of female Anopheles albimanus saliva

Salivary glands of female mosquitoes produce proteins, not completely described yet, that participate in carbohydrate and blood feeding. Here, we report an acidic glycoprotein of 35 kDa (GP35 ANOAL) secreted in the saliva of the malaria vector mosquito Anopheles albimanus. GP35 ANOAL is produced exclusively in the distal lateral lobes of adult female salivary glands, it has a pI of 4.45 and is negatively stained by regular silver stain. An 888 bp cDNA clone encoding a predicted product of 240 amino acids has a signal peptide, potential post-translational modification sites, and a disintegrin signature RGD. The GP35 ANOAL sequence depicts high similarities with the 30 kDa saliva allergen of Aedes aegypti, 30 kDa allergen-like hypothetical proteins, and GE-rich proteins present in several Anopheles species, as well as in Ae. albopictus and Culex pipiens quinquefasciatus. The function of this protein family is still unknown.     

Developmentally regulated infectivity of malaria sporozoites for mosquito salivary glands and the vertebrate host

Sporozoites are an invasive stage of the malaria parasite in both the mosquito vector and the vertebrate host. We developed an in vivo assay for mosquito salivary gland invasion by preparing Plasmodium gallinaceum sporozoites from infected Aedes aegypti mosquitoes under physiological conditions and inoculating them into uninfected female Ae. aegypti. Sporozoites from mature oocysts were isolated from mosquito abdomens 10 or 11 d after an infective blood meal. Salivary gland sporozoites were isolated 13 or 14 d after an infective blood meal. Purified oocyst sporozoites that were inoculated into uninfected female mosquitoes invaded their salivary glands. Using the same assay system, sporozoites derived from salivary glands did not reinvade the salivary glands after inoculation. Conversely, as few as 10 to 50 salivary gland sporozoites induced infection in chickens, while only 2 of 10 chickens inoculated with 5,000 oocyst sporozoites were infected. Both sporozoite populations were found to express a circumsporozoite protein on the sporozoite surface as determined by immunofluorescence assay and circumsporozoite precipitation test using a circumsporozoite protein-specific monoclonal antibody. We conclude that molecules other than this circumsporozoite protein may be responsible for the differential invasion of mosquito salivary glands or infection of the vertebrate host.     

A cluster of four D7-related genes is expressed in the salivary glands of the African malaria vector Anopheles gambiae

Four genes expressed in the Anopheles gambiae adult female salivary glands and similar in sequence to the Aedes aegypti D7 gene were identified. The genes, called D7-related (D7r), are included in a single cluster encompassing approximately six kilobases on chromosome arm 3R. The deduced proteins contain secretory signals and they are probably injected by the mosquito into the host with the saliva during blood feeding. The region of similarity to D7 encompasses the carboxy-terminal part of the Ae. aegypti protein and the different An. gambiae D7r show a degree of similarity to each other, varying from 53% to 73%. The weak but significant similarity to members of a wide family of insect proteins, including odourant- and pheromone-binding proteins, raises the possibility that the D7r-encoded proteins may bind and/or carry small hydrophobic ligands.     

Expression of Orseolia oryzae nucleoside diphosphate kinase (OoNDPK) is enhanced in rice gall midge feeding on susceptible rice hosts and its over‐expression leads to salt tolerance in Escherichia coli

The Asian rice gall midge, Orseolia oryzae, is a major dipteran pest of rice, with many known biotypes. The present investigation was initiated to understand the molecular mechanisms of infestation for developing novel integrated pest management strategies. We isolated and characterized a gene, nucleoside diphosphate kinase (OoNDPK), from the rice gall midge, encoding a protein with 169 amino acid residues and with a secretory signal sequence – an observation that assumes significance as salivary gland secretions have been implicated to play a major role in insect?plant interactions. Furthermore, up‐regulation (> 18 folds) of OoNDPK was observed in the salivary glands of maggots feeding on susceptible host in contrast to those feeding on resistant host. Phylogenetic analysis revealed similarity of OoNDPK with its dipteran orthologues. 3DLigandSite analysis, of the predicted OoNDPK and its orthologues, revealed phenylalanine and tyrosine residues to be specifically present in NDPK proteins from the plant feeders. Results suggest secretion of OoNDPK into the host plant and its probable involvement in gall midge?rice interaction. Using the coleoptile cell elongation assay, we demonstrated that the recombinant OoNDPK is capable of causing elongation of rice coleoptile cells. Additionally, heterologous expression of OoNDPK in Escherichia coli increased the tolerance of these cells to salt (NaCl; up to 1 mM), hinting at the involvement of this gene in abiotic stress response as well.     

MAEBL is essential for malarial sporozoite infection of the mosquito salivary gland

Malarial sporozoites mature in the oocysts formed in the mosquito midgut wall and then selectively invade the salivary glands, where they wait to be transmitted to the vertebrate host via mosquito bite. Invasion into the salivary gland has been thought to be mediated by specific ligand-receptor interactions, but the molecules involved in these interactions remain unknown. MAEBL is a single transmembrane-like protein that is structurally related to merozoite adhesive proteins. We found MAEBL of the rodent malaria parasite, Plasmodium berghei, to be specifically produced by the sporozoites in the oocyst and localized in their micronemes, which are secretory organelles involved in malarial parasite invasion into the host cell. A targeted disruption experiment of the P. berghei MAEBL gene revealed that it was essential for sporozoite infection of the salivary gland and was involved in the attachment to the salivary gland surface. In contrast, the disruption of the MAEBL gene did not affect sporozoite motility in vitro nor infectivity to the vertebrate host. These results suggest that P. berghei MAEBL is a sporozoite attachment protein that participates in specific binding to and infection of the mosquito salivary gland.     

Identification and characterization of gp65, a salivary-gland-specific molecule expressed in the malaria vector Anopheles albimanus

A group of salivary-gland-specific proteins, designated gp65, were identified in the mosquito Anopheles albimanus. Two-dimensional gel electrophoresis resolved this group into at least four molecules with pI 6.4-6.5. The N-terminal amino acid sequence was determined for the major species, gp65-1, and degenerate oligonucleotide primers were used to amplify a specific probe for library screening. A 1312 bp cDNA clone encoding a predicted translation product of 386 amino acids was recovered. gp65-1 is expressed abundantly in the medial and distal-lateral lobes of the adult female glands, and is secreted in the saliva. The amino acid sequence has potential sites for N-glycosylation, phosphorylation and myristylation, and is similar to a number of proteins of unknown function from other mosquito species.     

Robust salivary gland-specific transgene expression in Anopheles stephensi mosquito

Malaria sporozoites invade the mosquito salivary glands and wait in the salivary duct until the next blood feeding. The mechanisms of the process and molecules involved in the salivary gland invasion remain largely unknown. To establish a robust salivary gland-specific transgene expression in Anopheles stephensi, we obtained a salivary gland-specific promoter for a gene encoding anopheline antiplatelet protein (AAPP). The aapp promoter is a female salivary gland-specific and blood meal-inducible strong promoter. Using this promoter, we generated a transgenic An. stephensi expressing abundant Discosoma sp. red fluorescent protein (DsRed) in the distal-lateral lobes of the glands, where the sporozoites invade preferentially. These results open up the possibilities of elucidating salivary gland-parasite interactions and generating transgenic mosquitoes refractory to parasites.     

Induction of antisporozoite antibodies by biting of transgenic Anopheles stephensi delivering malarial antigen via blood feeding

We produced a transgenic mosquito expressing a rodent malaria vaccine candidate antigen in the salivary gland. Three tandemly repeated amino acid units from the repeat region of circumsporozoite protein of Plasmodium berghei (PbCS3R) fused to red fluorescent protein (monomeric DsRed) was chosen as a vaccine candidate antigen. Immunoblot and fluorescence microscopic analyses showed the transgene expression in the female salivary gland. The transgene product was released from the proboscis as a component of saliva. The monomeric DsRed-fusion expression system could be suitable for transgene secretion in the saliva of female mosquitoes. Mice repeatedly bitten by transgenic mosquitoes raised antibodies against P. berghei sporozoites, and the sera had protective ability against sporozoite invasion of human hepatoma HepG2 cells. These results suggest that transgene products are immunogenically active in saliva, and induce the antibodies to malaria parasite. These findings indicate that this technology has the potential for production of a 'flying vaccinator' for rodent malaria parasites.     

NorM, a Putative Multidrug Efflux Protein, of Vibrio parahaemolyticus and Its Homolog in Escherichia coli

We found that cells of Vibrio parahaemolyticus possess an energy-dependent efflux system for norfloxacin. We cloned a gene for a putative norfloxacin efflux protein from the chromosomal DNA of V. parahaemolyticus by using an Escherichia coli mutant lacking the major multidrug efflux system AcrAB as the host and sequenced the gene (norM). Cells of E. coli transformed with a plasmid carrying the norM gene showed elevated energy-dependent efflux of norfloxacin. The transformants showed elevated resistance not only to norfloxacin and ciprofloxacin but also to the structurally unrelated compounds ethidium, kanamycin, and streptomycin. These results suggest that this is a multidrug efflux system. The hydropathy pattern of the deduced amino acid sequence of NorM suggested the presence of 12 transmembrane domains. The deduced primary structure of NorM showed 57% identity and 88% similarity with that of a hypothetical E. coli membrane protein, YdhE. No reported drug efflux protein in the sequence databases showed significant sequence similarity with NorM. Thus, NorM seems to be a novel type of multidrug efflux protein. We cloned the ydhE gene from E. coli. Cells of E. coli transformed with the cloned ydhE gene showed elevated resistance to norfloxacin, ciprofloxacin, acriflavine, and tetraphenylphosphonium ion, but not to ethidium, when MICs were measured. Thus, it seems that NorM and YdhE differ somehow in substrate specificity.