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Discover the Microbes Within! The Wolbachia Project. 1,000,000,000,000,000,000 insects on the planetInsects present on earth for ~500 MY85% of all animal species are insects (1-30 million species)20% of all insect species harbor heritable symbionts called Wolbachia Scientists cant discover them
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1. Discover the Microbes Within! The Wolbachia Project
2. Discover the Microbes Within!The Wolbachia Project 1,000,000,000,000,000,000 insects on the planet
Insects present on earth for ~500 MY
85% of all animal species are insects (1-30 million species)
20% of all insect species harbor heritable symbionts called Wolbachia
Scientists cant discover them all on their own.
YOU ARE OUR BIGGEST ASSET TO SCIENTIFIC DISCOVERY AND REAL RESEARCH!
3. What is symbiosis? The living together of dissimilar organisms (de Bary 1859)
Often for mutual benefit, but also parasitism and commensalism
Endosymbiosis is when one organism lives and replicates inside another one
4. Vertically-transmitted(i.e., Inherited) Symbionts
8. Reproductive Parasites
10. Wolbachia are Infectious Widowmakers!
11. Phylogeny of Wolbachia Phylogeny of Wolbachia. a | The phylogenetic relationships of Wolbachia relative to the closely related Rickettsiales order in the Anaplasmataceae family. b | An unrooted phylogenetic tree of the main supergroups of Wolbachia. Also shown are the dominant patterns of mutualism and reproductive parasitism across the supergroups. For some supergroups, functional effects of Wolbachia have not yet been determined. The G supergroup has been removed because its status is currently unclear8. The pattern suggests that the main supergroups of Wolbachia participate in either mutualism or reproductive parasitism. Rooting of the Wolbachia phylogeny, which could help resolve whether mutualism or reproductive parasitism is ancestral, is problematic owing to long-branch attraction to out-groups. Resolution requires genome-sequence information for additional taxa. Triangle size represents described diversity within each lineage. Circles represent a lineage based on a single Wolbachia strain. Part a reproduced from REF. 98. Part b reproduced, with permission, from REF. 99 (2007) Society for General Microbiology.Phylogeny of Wolbachia. a | The phylogenetic relationships of Wolbachia relative to the closely related Rickettsiales order in the Anaplasmataceae family. b | An unrooted phylogenetic tree of the main supergroups of Wolbachia. Also shown are the dominant patterns of mutualism and reproductive parasitism across the supergroups. For some supergroups, functional effects of Wolbachia have not yet been determined. The G supergroup has been removed because its status is currently unclear8. The pattern suggests that the main supergroups of Wolbachia participate in either mutualism or reproductive parasitism. Rooting of the Wolbachia phylogeny, which could help resolve whether mutualism or reproductive parasitism is ancestral, is problematic owing to long-branch attraction to out-groups. Resolution requires genome-sequence information for additional taxa. Triangle size represents described diversity within each lineage. Circles represent a lineage based on a single Wolbachia strain. Part a reproduced from REF. 98. Part b reproduced, with permission, from REF. 99 (2007) Society for General Microbiology.
12. Wolbachia Induced Phenotypes Wolbachia-induced phenotypes. Wolbachia cause four distinct reproductive phenotypes in a range of arthropod orders (top). Feminization results in genetic males that develop as females (in the Hemiptera, Isopoda and Lepidoptera orders). Parthenogenesis induction eliminates males from reproduction (in the Acari, Hymenoptera and Thysanoptera orders). Male killing eliminates infected males to the advantage of surviving infected female siblings (in the Coleoptera, Diptera, Lepidoptera and Pseudoscorpiones orders). Cytoplasmic incompatibility
prevents infected males from successfully mating with females that lack the same Wolbachia types (in the Acari, Coleoptera, Diptera, Hemiptera, Hymenoptera, Isopoda, Lepidoptera and Orthoptera orders). A cross section of a male filarial nematode, Onchocerca ochengi, that contains Wolbachia is shown (bottom left), in which Wolbachia are falsely coloured yellow and fill three of the four syncytial lateral cord cells. Wolbachia (yellow) are also shown within the ovaries of a female Drosophila simulans (bottom right). The image on the bottom left is courtesy of M. Taylor, Liverpool School of Tropical Medicine, UK. The image on the bottom right is courtesy of M. Clark, University of Rochester, New York, USA.Wolbachia-induced phenotypes. Wolbachia cause four distinct reproductive phenotypes in a range of arthropod orders (top). Feminization results in genetic males that develop as females (in the Hemiptera, Isopoda and Lepidoptera orders). Parthenogenesis induction eliminates males from reproduction (in the Acari, Hymenoptera and Thysanoptera orders). Male killing eliminates infected males to the advantage of surviving infected female siblings (in the Coleoptera, Diptera, Lepidoptera and Pseudoscorpiones orders). Cytoplasmic incompatibility
prevents infected males from successfully mating with females that lack the same Wolbachia types (in the Acari, Coleoptera, Diptera, Hemiptera, Hymenoptera, Isopoda, Lepidoptera and Orthoptera orders). A cross section of a male filarial nematode, Onchocerca ochengi, that contains Wolbachia is shown (bottom left), in which Wolbachia are falsely coloured yellow and fill three of the four syncytial lateral cord cells. Wolbachia (yellow) are also shown within the ovaries of a female Drosophila simulans (bottom right). The image on the bottom left is courtesy of M. Taylor, Liverpool School of Tropical Medicine, UK. The image on the bottom right is courtesy of M. Clark, University of Rochester, New York, USA.
14. Wolbachia-to-host lateral gene transfer in Drosophila ananassae Wolbachia-to-host lateral gene transfer in Drosophila ananassae. Almost the entire Wolbachia genome (green) has been transferred into the second chromosome of D. ananassae (blue). Following this lateral gene transfer, D. ananassae transposable elements (TEs) have become inserted within Wolbachia genes. At least 28 Wolbachia genes are transcribed from within the D. ananassae genome, although the functional significance of this is unknown.Wolbachia-to-host lateral gene transfer in Drosophila ananassae. Almost the entire Wolbachia genome (green) has been transferred into the second chromosome of D. ananassae (blue). Following this lateral gene transfer, D. ananassae transposable elements (TEs) have become inserted within Wolbachia genes. At least 28 Wolbachia genes are transcribed from within the D. ananassae genome, although the functional significance of this is unknown.
16. The Wolbachia Pandemic
18. Number of scientific papers with Wolbachia in title
19. How Important Are Wolbachia?
20. Human Health: Wolbachia may help control the transmission of arthropod-borne diseases
22. Population Replacement
24. 24
25. Wolbachia are Chemotherapy Targets for Curing River Blindness & Elephantiasis Caused By Filarial Nematodes
26. 26 Tissue Nematode (Roundworm): Onchocerca volvulus and River Blindness Transmitted by biting black flies
Larvae develop into adults in subcutaneous tissues
Adult females migrate via the blood to the eyes, provoking inflammatory reactions
Coinfection with Wolbachia bacteria causes river blindness
Treatment: tetracycline and ivermectin
27. Overview of Onchocerciasis River blindness is the symptomatic stage of a filarial infection
It is a painful and debilitating disease.
18 million people in Africa are infected
28. Overview of Onchocerciasis Symptoms include: visual impairment, rashes, lesions, intense itching, depigmentation, inflammation of lymph nodes, and general debilitation.
29. Overview of Onchocerciasis Disease is the result of infection by the parasitic worm, Onchocerca volvulus.
Females produce millions of microfilariae that migrate through the body and cause a manifestation of symptoms
30. Overview of Onchocerciasis Simulans spp. (black flies) are vectors
Female black flies require a blood meal prior to egg laying
Microfilariae are taken in with infected blood
Transfer takes place when the fly bites uninfected person
31. CDC/DPD Summary Report 2001 Black flies are infected with Wolbachia bacteria
Worldwide distribution
Infection rates have been found to be up to 76% of insects in some regions
Also found in millipedes, crustaceans, and mites
Wolbachia is passed horizontally and vertically
33. 33 Tissue Nematode (Roundworm): Wuchereria bancrofti Tropical infection spread by mosquitoes
Vector deposits larvae which move into lymphatics and develop
Chronic infection causes blockage of lymphatic circulation and elephantitis, massive swelling in the extremities
34. 34 Tissue Nematode (Roundworm): Filariasis due to W. bancrofti Endemic in central Africa, Mediterranean coast, parts of Asia (China, Korea, Japan, the Philippines)
Blood specimens may show microfilariae
Acute symptoms include: fever, lymphangitis/lymphadenitis
Result of inflammatory response to molting adolescent worms and dead adults in lymphatic vessels
May involve any part of body, blocking lymphatic system
35. 35 Tissue Nematode (Roundworm): Elephantitis
36. 36 Elephantiasis: Wucheria bancrofti
37. How do YOU discover the Wolbachia within?
38. Integrated Set of Lab ExercisesFrom Organisms to Molecules and Back!
39. Features of These Labs Original Research in Lab Exercises
49. Where Does Your Data Go? Class reports
Peers, family, teachers, research scientists
Online database (website repository for your data)
New discoveries
Collaborations between research scientists and high schools
Summer envisionships
Professional meetings
Professional societies
Journal publications