Judy Coleman scite author profile

BackgroundAedes aegypti mosquitoes are the main vectors of dengue viruses to humans. Understanding their biology and interactions with the pathogen are prerequisites for development of dengue transmission control strategies. Mosquito salivary glands are organs involved directly in pathogen transmission to vertebrate hosts. Information on the spatial distribution of gene expression in these organs is expected to assist in the development of novel disease control strategies, including those that entail the release of transgenic mosquitoes with impaired vector competence.ResultsWe report here the hybridization in situ patterns of 30 transcripts expressed in the salivary glands of adult Ae. aegypti females. Distinct spatial accumulation patterns were identified. The products of twelve genes are localized exclusively in the proximal-lateral lobes. Among these, three accumulate preferentially in the most anterior portion of the proximal-lateral lobe. This pattern revealed a salivary gland cell type previously undescribed in Ae. aegypti, which was validated by transmission electron microscopy. Five distinct gene products accumulate in the distal-lateral lobes and another five localize in the medial lobe. Seven transcripts are found in the distal-lateral and medial lobes. The transcriptional product of one gene accumulates in proximal- and distal-lateral lobes. Seven genes analyzed by quantitative PCR are expressed constitutively. The most abundant salivary gland transcripts are those localized within the proximal-lateral lobes, while previous work has shown that the distal-lateral lobes are the most active in protein synthesis. This incongruity suggests a role for translational regulation in mosquito saliva production.ConclusionsTransgenic mosquitoes with reduced vector competence have been proposed as tools for the control of dengue virus transmission. Expression of anti-dengue effector molecules in the distal-lateral lobes of Ae. aegypti salivary glands has been shown to reduce prevalence and mean intensities of viral infection. We anticipate greater efficiency of viral suppression if effector genes are expressed in all lobes of the salivary glands. Based on our data, a minimum of two promoters is necessary to drive the expression of one or more anti-dengue genes in all cells of the female salivary glands.

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Virus-expressed, recombinant single-chain antibody blocks sporozoite infection of salivary glands in Plasmodium gallinaceum-infected Aedes aegypti.

Capurro¹,

Coleman²,

Beerntsen³

et al. 2000

125

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Transgenic mosquitoes resistant to malaria parasites are being developed to test the hypothesis that they may be used to control disease transmission. We have developed an effector portion of an antiparasite gene that can be used to test malaria resistance in transgenic mosquitoes. Mouse monoclonal antibodies that recognize the circumsporozoite protein of Plasmodium gallinaceum can block sporozoite invasion of Aedes aegypti salivary glands. An anti-circumsporozoite monoclonal antibody, N2H6D5, whose corresponding heavy-and light-chain gene variable regions were engineered as a single-chain antibody construct, binds to P. gallinaceum sporozoites and prevents infection of Ae. aegypti salivary glands when expressed from a Sindbis virus. Mean intensities of sporozoite infections of salivary glands in mosquitoes expressing N2scFv were reduced as much as 99.9% when compared to controls.

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Characterization of the Sialokinin I gene encoding the salivary vasodilator of the yellow fever mosquito, Aedes aegypti

Beerntsen

Champagne

Coleman

et al. 1999

Insect Molecular Biology

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The gene encoding sialokinin I, the principal vasodilatory peptide of Aedes aegypti, has been isolated and characterized. Degenerate oligonucleotide primers based on peptide amino acid sequence were used to amplify a gene fragment from messenger RNA (mRNA) isolated from female salivary glands. The amplification product was used to probe a salivary gland complementary DNA (cDNA) library, and a number of corresponding cDNAs were isolated and their primary sequence determined. Analysis of the conceptual translation product of a 406-bp cDNA indicates that sialokinin I is expressed as a preprosialokinin and is subsequently post-translationally processed to the active peptide. Northern analysis revealed a 490-bp transcription product expressed exclusively in female salivary glands, and hybridization in situ of probes to RNA in whole tissues localized gene expression to the medial lobe of female salivary glands. Screening of an Ae. aegypti genomic library with the cDNA resulted in the isolation of a clone containing the gene, designated Sialokinin I (Sia I). Comparison of the cDNA with the genomic clone reveals two introns of 62 bp and 833 bp. Primer extension analysis showed that several transcription initiation sites are present. Southern analysis of genomic DNA shows that Sia I is most probably a single-copy gene. Similarities of the Sia I gene product with other genes are confined to the region encoding the active decapeptide.

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Genetic Control of Malaria Parasite Transmission: Threshold Levels for Infection in an Avian Model System

Jasinskiene

Coleman²,

Ashikyan³

et al. 2007

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Genetic strategies for controlling malaria transmission based on engineering pathogen resistance in Anopheles mosquitoes are being tested in a number of animal models. A key component is the effector molecule and the efficiency with which it reduces parasite transmission. Single-chain antibodies (scFvs) that bind the circumsporozoite protein of the avian parasite, Plasmodium gallinaceum, can reduce mean intensities of sporozoite infection of salivary glands by two to four orders of magnitude in transgenic Aedes aegypti. Significantly, mosquitoes with as few as 20 sporozoites in their salivary glands are infectious for a vertebrate host, Gallus gallus. Although scFvs hold promise as effector molecules, they will have to reduce mean intensities of infection to zero to prevent parasite transmission and disease. We conclude that similar endpoints must be reached with human pathogens if we are to expect an effect on disease transmission.

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Dissection of Midgut and Salivary Glands from Ae. aegypti Mosquitoes

Coleman

Juhn

James

2007

JoVE

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The mosquito midgut and salivary glands are key entry and exit points for pathogens such as Plasmodium parasites and Dengue viruses. This video protocol demonstrates dissection techniques for removal of the midgut and salivary glands from Aedes aegypti mosquitoes. Video LinkThe video component of this article can be found at http://www.jove.com/video/228/ ProtocolDissection of midgut and salivary gland tissues from mosquitoes requires prior preparation of 1X Phosphate Buffered Saline (1X PBS) solution and anesthetization of mosquitoes by subjecting to a temperature of 4°C, until immobilized. The mosquitoes remain anesthetized by placing in a Petri dish that is kept cold on ice. Other materials required include: light microscope fitted with 10x objective, pipettor, fine-tipped forceps, glass slide, needle-tip probes. Midgut dissection1. Place a drop of 1X PBS onto a glass slide mounted under the light microscope. 2. Transfer a mosquito onto the prepared slide by stabbing the mosquito thorax with a needle-tip probe. 3. While holding down the mosquito with the probe, use the forceps to grasp the second to the last abdominal segment and gently pull off the mosquito abdomen in a single motion. The midgut should remain attached to the immobilized thorax. 4. Discard the abdomen. Use the forceps to detach the midgut from the thorax. Salivary gland dissection1. Place a drop of 1X PBS onto a glass slide mounted under a light microscope. 2. Pick up a mosquito by stabbling the thorax with a needle-tip probe. 3. Pull off mosquito legs using your fingers. 4. Transfer the mosquito onto the slide. 5. Remove the head of the mosquito using forceps. 6. While holding down the mosquito thorax with the probe, use another probe to gently push down on the thorax. 7. The salivary glands are located at the anterior portion of the thorax and can be isolated by using a needle-tip probe and severing the attachments that connect the gland to the thorax. Intact salivary glands are comprised of three lobes: two lateral lobes and a medial lobe. DisclosuresThe authors have nothing to disclose.

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Judy Coleman

Spatial mapping of gene expression in the salivary glands of the dengue vector mosquito, Aedes aegypti

Virus-expressed, recombinant single-chain antibody blocks sporozoite infection of salivary glands in Plasmodium gallinaceum-infected Aedes aegypti.

Characterization of the Sialokinin I gene encoding the salivary vasodilator of the yellow fever mosquito, Aedes aegypti

Genetic Control of Malaria Parasite Transmission: Threshold Levels for Infection in an Avian Model System

Dissection of Midgut and Salivary Glands from Ae. aegypti Mosquitoes

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