| NSF Org: |
IOS Division Of Integrative Organismal Systems |
| Recipient: |
|
| Initial Amendment Date: | April 13, 2015 |
| Latest Amendment Date: | May 7, 2018 |
| Award Number: | 1456778 |
| Award Instrument: | Continuing Grant |
| Program Manager: |
Mamta Rawat
mrawat@nsf.gov (703)292-7265 IOS Division Of Integrative Organismal Systems BIO Directorate for Biological Sciences |
| Start Date: | May 1, 2015 |
| End Date: | April 30, 2020 (Estimated) |
| Total Intended Award Amount: | $957,522.00 |
| Total Awarded Amount to Date: | $957,522.00 |
| Funds Obligated to Date: |
FY 2016 = $199,999.00 FY 2017 = $199,999.00 FY 2018 = $300,000.00 |
| History of Investigator: |
|
| Recipient Sponsored Research Office: |
110 21ST AVE S NASHVILLE TN US 37203-2416 (615)322-2631 |
| Sponsor Congressional District: |
|
| Primary Place of Performance: |
465 21st Avenue Nashville TN US 37232-2635 |
| Primary Place of
Performance Congressional District: |
|
| Unique Entity Identifier (UEI): |
|
| Parent UEI: |
|
| NSF Program(s): | Symbiosis Infection & Immunity |
| Primary Program Source: |
01001617DB NSF RESEARCH & RELATED ACTIVIT 01001718DB NSF RESEARCH & RELATED ACTIVIT 01001819DB NSF RESEARCH & RELATED ACTIVIT |
| Program Reference Code(s): |
|
| Program Element Code(s): |
|
| Award Agency Code: | 4900 |
| Fund Agency Code: | 4900 |
| Assistance Listing Number(s): | 47.074 |
ABSTRACT
At the turn of the 20th century, biologists asserted that babies develop within a sterile womb and acquire their initial bacteria from the environment. While this paradigm is under preliminary reconsideration today in light of new technologies and analyses, comparative studies of animals have long held that maternal provisioning of bacteria to offspring is widespread, spanning the base of the animal kingdom to vertebrates. Moreover, such bacteria are not simply innocuous passengers. They impart vital consequences to animal health and disease, and they have their own microbial interests, namely their propagation from mother to the next generation. In this context, there is a biological conundrum between host and maternally transmitted bacteria. High loads of bacteria can lead to pathogenesis in the animal offspring while low concentrations can lead to loss of the bacteria. Balancing these opposing outcomes in the middle is one possible way to reconcile the extremes. Thus, the critical biological question is how are the concentrations of maternally transmitted bacteria regulated? Using a preeminent animal-microbe model, the investigators will genetically test the hypotheses that (i) animal hosts express multiple (rather than single) genes to control the concentrations of maternally transmitted bacteria (ii) when these genes are disrupted from their normal functions, the bacterial densities transmitted to the offspring will increase and (iii) these genes control the bacteria by preventing them from entering the developing offspring and repressing their replication. This project will be the first study to deploy a unique genetic analysis that characterizes the animal genes that keep bacterial densities in check. The Principal Investigator will direct a one-week workshop for pre-service teachers (college students working towards a degree in education) based on the premise that the earlier that teachers participate in "discovery science", the more likely they will feel comfortable using it in the classrooms. The researchers will also partner with the School for Science and Math at Vanderbilt to develop a Community Engaged Research Project in which Nashville high school students transfer experiential learning from the research lab back to their classrooms to engage in the process of cooperative and peer-to-peer learning for science- and technology-related investigations.
The majority of animal species harbor maternally-transmitted bacteria, yet little is known about the genetic and molecular mechanisms that the animal and bacteria use to achieve maternal transmission. For symbionts transmitted via the germ-line, bacterial density can critically influence transmission efficiency and penetrance of symbiotic traits induced by the symbiont. This research begins the first forward-genetic investigation of host genes that regulate densities of Wolbachia pipientis. The genus Wolbachia is a model endosymbiont because it occurs in more animal species than any other bacterium on the planet, and it can range from a beneficial symbiont in filarial nematodes, a parasitic manipulator of arthropod reproduction, to the main inflammatory agent of human filarial diseases. However, despite infection's prevalence, few host-Wolbachia interactions have been identified that control their densities. As a model host with genetic tools, the Nasonia parasitoid wasp genus is comprised of several closely related species that harbor unique strains of maternally-transmitted Wolbachia in their reproductive tissues. Transfer of these Wolbachia strains between the interfertile Nasonia species can result in dramatic changes in infection titers and tissue tropism. Specifically, the wVitA strain maintains a low infection density in its natural host, Nasonia vitripennis, but has a wider tissue tropism and stable infection density 100-fold higher in the naive host, Nasonia giraulti. Quantitative trait loci analyses specify that the regulation of the low wVitA density maps to three N. vitripennis chromosomal regions. This host regulation acts dominantly through a maternal effect - the mother determines the densities of her offspring. Thus, the central hypothesis of this research project is that multiple genes involved in host innate immunity and/or oogenesis act maternally to regulate Wolbachia densities in offspring. The goal of this project is to utilize an unprecedented interspecific difference in Wolbachia titers to identify the numbers and types of host genes that regulate Wolbachia densities, their additive and epistatic interactions, and their effects on Wolbachia localization and proliferation during oogenesis.
PUBLICATIONS PRODUCED AS A RESULT OF THIS RESEARCH
Note:
When clicking on a Digital Object Identifier (DOI) number, you will be taken to an external
site maintained by the publisher. Some full text articles may not yet be available without a
charge during the embargo (administrative interval).
Some links on this page may take you to non-federal websites. Their policies may differ from
this site.
PROJECT OUTCOMES REPORT
Disclaimer
This Project Outcomes Report for the General Public is displayed verbatim as submitted by the Principal Investigator (PI) for this award. Any opinions, findings, and conclusions or recommendations expressed in this Report are those of the PI and do not necessarily reflect the views of the National Science Foundation; NSF has not approved or endorsed its content.
Broader Impacts
One of the central questions of biodiversity research is how do different species maintain long-term, stable relationships with each other? Answering this question is a major imperative in the life sciences because the living together of dissimilar organisms, or symbiosis, is a hallmark of biology. Plants and animals live in a world dominated by microorganisms (bacteria, viruses, etc.), and often these microorganisms live inside the cells of their hosts. For instance, bacteria within the cells of animals are occasionally inherited from parents to offspring. However, unlike most inherited genes, these bacteria possess the ability to self-replicate and can therefore proliferate inside animal bodies. Sometimes these relationships are to the animal host's detriment. This work focused on a particular group of two closely-related animal species of Nasonia parasitoid wasps that regulate an intracellular bacteria named Wolbachia at markedly different densities. The main goal was to understand the number and types of animal genes that regulate the change. As the most common inherited bacteria inside animals, including in insects, spiders, and mites, Wolbachia have recently been deployed in mosquito control strategies to prevent the transmission of dengue and Zika viruses to humans. However, the genetic basis of how various arthropod hosts like Nasonia naturally keep their bacteria in check is mostly unknown.
We uncovered five key results. First, there is approximately a 100-fold difference in the densities of Wolbachia bacteria between two Nasonia species, and the wasp DNA that controls this variation maps to two of the wasp's five chromosomes, supporting a simple genetic basis for the trait. Second, within one of the regions, the Wolbachia density suppressor gene Wds controls half of the difference in the bacterial densities, and notably this gene has no predicted function and appears restricted to wasp species and its close relatives. Thus, a single gene whose function is enigmatic and restricted to a small group of animals evolved to crucially control the densities of this bacteria. Third, Wds evolved under Darwinian natural selection in which mutations controlling the bacteria led to an increase in fitness of the wasp species by keeping the Wolbachia densities in check. Fourth, a second chromosomal region consisting of two segments controls the remaining half of the density variation. Fifth and finally, the Wds protein is expressed in ovaries in response to Wolbachia and localizes to cells that provide nutrients and surround the developing eggs of the next generation. Collectively, this work leads to a model in which a few genes, including ones that may function in highly specific and novel ways in the ovaries, encode products that suppress Wolbachia at the proximal site of inheritance in the mother's reproductive tissues. The discovery sets in motion future genetic and mechanistic studies across other animal systems to understand if animal genetic novelty and Darwinian adaptation often drive the evolution of long-term, stable symbioses.
Broader Impacts
There are two broader impacts of this work. First, the work continues to bridge the disciplines of symbiosis, genetics, entomology, evolution, and science education through training and participation of high school, undergraduate, and graduate students and postdocs, many of whom authored scientific papers and now have successful careers in academia, science policy, medicine, and more. Second, the work solidified and extended digital learning and online community sites as well as an award-winning science education and outreach platform ? Discover the Microbes Within! The Wolbachia Project. This five-part lab series teaches 1000's of students pear year nationally and internationally to engage in hands-on, discovery-based experiments in biodiversity, biotechnology, and bioinformatics. Some participants collaborate between schools across state or country borders, and all participants take full ownership of their science to make new discoveries in symbiosis.
Last Modified: 09/27/2020
Modified by: Seth Bordenstein
Please report errors in award information by writing to: awardsearch@nsf.gov.
