Your search keyword '"Wolbachia pathogenicity"' showing total 7 results

1. The phage gene wmk is a candidate for male killing by a bacterial endosymbiont.

Author

Perlmutter JI, Bordenstein SR, Unckless RL, LePage DP, Metcalf JA, Hill T, Martinez J, Jiggins FM, and Bordenstein SR

Subjects

Animals, Animals, Genetically Modified, DNA-Binding Proteins genetics, DNA-Binding Proteins physiology, Drosophila embryology, Drosophila microbiology, Drosophila virology, Drosophila melanogaster embryology, Drosophila melanogaster microbiology, Drosophila melanogaster virology, Female, Genes, Lethal, Genes, Viral, Host Microbial Interactions genetics, Host Microbial Interactions physiology, Male, Prophages physiology, Sex Ratio, Symbiosis genetics, Symbiosis physiology, Viral Proteins genetics, Viral Proteins physiology, Prophages genetics, Prophages pathogenicity, Wolbachia pathogenicity, Wolbachia virology

Abstract

Wolbachia are the most widespread maternally-transmitted bacteria in the animal kingdom. Their global spread in arthropods and varied impacts on animal physiology, evolution, and vector control are in part due to parasitic drive systems that enhance the fitness of infected females, the transmitting sex of Wolbachia. Male killing is one common drive mechanism wherein the sons of infected females are selectively killed. Despite decades of research, the gene(s) underlying Wolbachia-induced male killing remain unknown. Here using comparative genomic, transgenic, and cytological approaches in fruit flies, we identify a candidate gene in the eukaryotic association module of Wolbachia prophage WO, termed WO-mediated killing (wmk), which transgenically causes male-specific lethality during early embryogenesis and cytological defects typical of the pathology of male killing. The discovery of wmk establishes new hypotheses for the potential role of phage genes in sex-specific lethality, including the control of arthropod pests and vectors., Competing Interests: J.I.P. and Seth R.B. are listed as inventors on a patent related to potential applications of wmk in arthropods.

Published

2019

2. Wolbachia utilize host actin for efficient maternal transmission in Drosophila melanogaster.

Author

Newton IL, Savytskyy O, and Sheehan KB

Subjects

Actins metabolism, Animals, Blotting, Western, Immunohistochemistry, In Situ Hybridization, Fluorescence, Infectious Disease Transmission, Vertical, Phenotype, Polymerase Chain Reaction, Drosophila melanogaster parasitology, Host-Parasite Interactions physiology, Wolbachia pathogenicity

Abstract

Wolbachia pipientis is a ubiquitous, maternally transmitted bacterium that infects the germline of insect hosts. Estimates are that Wolbachia infect nearly 40% of insect species on the planet, making it the most prevalent infection on Earth. The bacterium, infamous for the reproductive phenotypes it induces in arthropod hosts, has risen to recent prominence due to its use in vector control. Wolbachia infection prevents the colonization of vectors by RNA viruses, including Drosophila C virus and important human pathogens such as Dengue and Chikungunya. Here we present data indicating that Wolbachia utilize the host actin cytoskeleton during oogenesis for persistence within and transmission between Drosophila melanogaster generations. We show that phenotypically wild type flies heterozygous for cytoskeletal mutations in Drosophila profilin (chic(221/+) and chic(1320/+)) or villin (qua(6-396/+)) either clear a Wolbachia infection, or result in significantly reduced infection levels. This reduction of Wolbachia is supported by PCR evidence, Western blot results and cytological examination. This phenotype is unlikely to be the result of maternal loading defects, defects in oocyte polarization, or germline stem cell proliferation, as the flies are phenotypically wild type in egg size, shape, and number. Importantly, however, heterozygous mutant flies exhibit decreased total G-actin in the ovary, compared to control flies and chic(221) heterozygous mutants exhibit decreased expression of profilin. Additionally, RNAi knockdown of profilin during development decreases Wolbachia titers. We analyze evidence in support of alternative theories to explain this Wolbachia phenotype and conclude that our results support the hypothesis that Wolbachia utilize the actin skeleton for efficient transmission and maintenance within Drosophila.

Published

2015

3. High virulence of Wolbachia after host switching: when autophagy hurts.

Author

Le Clec'h W, Braquart-Varnier C, Raimond M, Ferdy JB, Bouchon D, and Sicard M

Subjects

Animals, Central Nervous System metabolism, Central Nervous System microbiology, Central Nervous System ultrastructure, Isopoda, Rickettsiaceae Infections microbiology, Species Specificity, Vacuoles metabolism, Vacuoles microbiology, Vacuoles ultrastructure, Wolbachia ultrastructure, Autophagy, Host-Pathogen Interactions, Rickettsiaceae Infections metabolism, Wolbachia pathogenicity, Wolbachia physiology

Abstract

Wolbachia are widespread endosymbionts found in a large variety of arthropods. While these bacteria are generally transmitted vertically and exhibit weak virulence in their native hosts, a growing number of studies suggests that horizontal transfers of Wolbachia to new host species also occur frequently in nature. In transfer situations, virulence variations can be predicted since hosts and symbionts are not adapted to each other. Here, we describe a situation where a Wolbachia strain (wVulC) becomes a pathogen when transfected from its native terrestrial isopod host species (Armadillidium vulgare) to another species (Porcellio d. dilatatus). Such transfer of wVulC kills all recipient animals within 75 days. Before death, animals suffer symptoms such as growth slowdown and nervous system disorders. Neither those symptoms nor mortalities were observed after injection of wVulC into its native host A. vulgare. Analyses of wVulC's densities in main organs including Central Nervous System (CNS) of both naturally infected A. vulgare and transfected P. d. dilatatus and A. vulgare individuals revealed a similar pattern of host colonization suggesting an overall similar resistance of both host species towards this bacterium. However, for only P. d. dilatatus, we observed drastic accumulations of autophagic vesicles and vacuoles in the nerve cells and adipocytes of the CNS from individuals infected by wVulC. The symptoms and mortalities could therefore be explained by this huge autophagic response against wVulC in P. d. dilatatus cells that is not triggered in A. vulgare. Our results show that Wolbachia (wVulC) can lead to a pathogenic interaction when transferred horizontally into species that are phylogenetically close to their native hosts. This change in virulence likely results from the autophagic response of the host, strongly altering its tolerance to the symbiont and turning it into a deadly pathogen.

Published

2012

4. Wolbachia infections are virulent and inhibit the human malaria parasite Plasmodium falciparum in Anopheles gambiae.

Author

Hughes GL, Koga R, Xue P, Fukatsu T, and Rasgon JL

Subjects

Animals, Anopheles immunology, Gene Expression, Host-Parasite Interactions, Humans, In Situ Hybridization, Fluorescence, Malaria, Falciparum parasitology, Malaria, Falciparum prevention & control, Oocysts growth & development, Plasmodium falciparum immunology, Polymerase Chain Reaction, Wolbachia genetics, Anopheles microbiology, Anopheles parasitology, Plasmodium falciparum growth & development, Wolbachia pathogenicity

Abstract

Endosymbiotic Wolbachia bacteria are potent modulators of pathogen infection and transmission in multiple naturally and artificially infected insect species, including important vectors of human pathogens. Anopheles mosquitoes are naturally uninfected with Wolbachia, and stable artificial infections have not yet succeeded in this genus. Recent techniques have enabled establishment of somatic Wolbachia infections in Anopheles. Here, we characterize somatic infections of two diverse Wolbachia strains (wMelPop and wAlbB) in Anopheles gambiae, the major vector of human malaria. After infection, wMelPop disseminates widely in the mosquito, infecting the fat body, head, sensory organs and other tissues but is notably absent from the midgut and ovaries. Wolbachia initially induces the mosquito immune system, coincident with initial clearing of the infection, but then suppresses expression of immune genes, coincident with Wolbachia replication in the mosquito. Both wMelPop and wAlbB significantly inhibit Plasmodium falciparum oocyst levels in the mosquito midgut. Although not virulent in non-bloodfed mosquitoes, wMelPop exhibits a novel phenotype and is extremely virulent for approximately 12-24 hours post-bloodmeal, after which surviving mosquitoes exhibit similar mortality trajectories to control mosquitoes. The data suggest that if stable transinfections act in a similar manner to somatic infections, Wolbachia could potentially be used as part of a strategy to control the Anopheles mosquitoes that transmit malaria.

Published

2011

5. Wolbachia infections in Anopheles gambiae cells: transcriptomic characterization of a novel host-symbiont interaction.

Author

Hughes GL, Ren X, Ramirez JL, Sakamoto JM, Bailey JA, Jedlicka AE, and Rasgon JL

Subjects

Animals, Anopheles genetics, Biomarkers metabolism, Drosophila genetics, Drosophila microbiology, Gene Expression Profiling, Humans, Oligonucleotide Array Sequence Analysis, RNA, Messenger genetics, Reverse Transcriptase Polymerase Chain Reaction, Anopheles metabolism, Anopheles microbiology, Malaria genetics, Malaria microbiology, Wolbachia metabolism, Wolbachia pathogenicity

Abstract

The endosymbiotic bacterium Wolbachia is being investigated as a potential control agent in several important vector insect species. Recent studies have shown that Wolbachia can protect the insect host against a wide variety of pathogens, resulting in reduced transmission of parasites and viruses. It has been proposed that compromised vector competence of Wolbachia-infected insects is due to up-regulation of the host innate immune system or metabolic competition. Anopheles mosquitoes, which transmit human malaria parasites, have never been found to harbor Wolbachia in nature. While transient somatic infections can be established in Anopheles, no stable artificially-transinfected Anopheles line has been developed despite numerous attempts. However, cultured Anopheles cells can be stably infected with multiple Wolbachia strains such as wAlbB from Aedes albopictus, wRi from Drosophila simulans and wMelPop from Drosophila melanogaster. Infected cell lines provide an amenable system to investigate Wolbachia-Anopheles interactions in the absence of an infected mosquito strain. We used Affymetrix GeneChip microarrays to investigate the effect of wAlbB and wRi infection on the transcriptome of cultured Anopheles Sua5B cells, and for a subset of genes used quantitative PCR to validate results in somatically-infected Anopheles mosquitoes. Wolbachia infection had a dramatic strain-specific effect on gene expression in this cell line, with almost 700 genes in total regulated representing a diverse array of functional classes. Very strikingly, infection resulted in a significant down-regulation of many immune, stress and detoxification-related transcripts. This is in stark contrast to the induction of immune genes observed in other insect hosts. We also identified genes that may be potentially involved in Wolbachia-induced reproductive and pathogenic phenotypes. Somatically-infected mosquitoes had similar responses to cultured cells. The data show that Wolbachia has a profound and unique effect on Anopheles gene expression in cultured cells, and has important implications for mechanistic understanding of Wolbachia-induced phenotypes and potential novel strategies to control malaria.

Published

2011

6. A cellular basis for Wolbachia recruitment to the host germline.

Author

Serbus LR and Sullivan W

Subjects

Animals, Female, Infectious Disease Transmission, Vertical, Microscopy, Confocal, Microtubules microbiology, Oocytes cytology, Oocytes physiology, Oogenesis, Wolbachia physiology, Drosophila Proteins metabolism, Drosophila melanogaster microbiology, Host-Pathogen Interactions, Insect Vectors microbiology, Kinesins metabolism, Oocytes microbiology, Wolbachia pathogenicity

Abstract

Wolbachia are among the most widespread intracellular bacteria, carried by thousands of metazoan species. The success of Wolbachia is due to efficient vertical transmission by the host maternal germline. Some Wolbachia strains concentrate at the posterior of host oocytes, which promotes Wolbachia incorporation into posterior germ cells during embryogenesis. The molecular basis for this localization strategy is unknown. Here we report that the wMel Wolbachia strain relies upon a two-step mechanism for its posterior localization in oogenesis. The microtubule motor protein kinesin-1 transports wMel toward the oocyte posterior, then pole plasm mediates wMel anchorage to the posterior cortex. Trans-infection tests demonstrate that factors intrinsic to Wolbachia are responsible for directing posterior Wolbachia localization in oogenesis. These findings indicate that Wolbachia can direct the cellular machinery of host oocytes to promote germline-based bacterial transmission. This study also suggests parallels between Wolbachia localization mechanisms and those used by other intracellular pathogens.

Published

2007

7. Wolbachia utilizes host microtubules and Dynein for anterior localization in the Drosophila oocyte.

Author

Ferree PM, Frydman HM, Li JM, Cao J, Wieschaus E, and Sullivan W

Subjects

Animals, Cell Differentiation physiology, Female, Molecular Sequence Data, Oocytes cytology, Oogenesis, Wolbachia growth & development, Wolbachia physiology, Drosophila melanogaster microbiology, Microtubules microbiology, Oocytes microbiology, Oocytes physiology, Wolbachia pathogenicity

Abstract

To investigate the role of the host cytoskeleton in the maternal transmission of the endoparasitic bacteria Wolbachia, we have characterized their distribution in the female germ line of Drosophila melanogaster. In the germarium, Wolbachia are distributed to all germ cells of the cyst, establishing an early infection in the cell destined to become the oocyte. During mid-oogenesis, Wolbachia exhibit a distinct concentration between the anterior cortex and the nucleus in the oocyte, where many bacteria appear to contact the nuclear envelope. Following programmed rearrangement of the microtubule network, Wolbachia dissociate from this anterior position and become dispersed throughout the oocyte. This localization pattern is distinct from mitochondria and all known axis determinants. Manipulation of microtubules and cytoplasmic Dynein and Dynactin, but not Kinesin-1, disrupts anterior bacterial localization in the oocyte. In live egg chambers, Wolbachia exhibit movement in nurse cells but not in the oocyte, suggesting that the bacteria are anchored by host factors. In addition, we identify mid-oogenesis as a period in the life cycle of Wolbachia in which bacterial replication occurs. Total bacterial counts show that Wolbachia increase at a significantly higher rate in the oocyte than in the average nurse cell, and that normal Wolbachia levels in the oocyte depend on microtubules. These findings demonstrate that Wolbachia utilize the host microtubule network and associated proteins for their subcellular localization in the Drosophila oocyte. These interactions may also play a role in bacterial motility and replication, ultimately leading to the bacteria's efficient maternal transmission.

Published

2005