Fact Sheet
Overview | Description | Applications | Operations | Results | Publications | Images
Experiment/Payload OverviewBrief Summary
Streptococcus pneumoniae Expression of Gene in Space (SPEGIS) will examine the behavior and growth of bacteria in microgravity and investigate the effects of the space environment on the gene expression, protein production, and virulence of the bacteria Streptococcus pneumoniae. The data collected will also provide insight on what types of bacterial infections may occur during long-duration space missions and the risks to crew members.
Principal InvestigatorInformation Pending
Payload DeveloperAmes Research Center, Moffett Field, CA
Sponsoring AgencyNational Aeronautics and Space Administration (NASA)
Expeditions Assigned|15|
Previous ISS MissionsWhile SPEGIS is a new experiment, other studies of microbial virulence have been conducted aboard ISS.
Experiment/Payload Description
Research Summary
- During spaceflight, as well as on Earth, humans risk infection that is caused by bacteria.
- This investigation will examine gene and protein expression of Streptococcus pneumoniae (a bacteria that is normally found living in the human body) are effected by microgravity.
- Data from SPEGIS is anticipated to provide information on the threat of opportunistic pathogens in the space environment, which will assist in the development of diagnostic tools to monitor the atmosphere and surfaces (air, soil, and food) for the presence of these microbes.
The Streptococcus pneumoniae Expression of Genes in Space (SPEGIS) will investigate S. pneumoniae gene expression and protein production in the space environment. S. pneumoniae is an important human pathogen and the leading cause of bacterial pneumonia (inflammation of the lungs with congestion), meningitis (inflammation of the membrane covering the brain and spinal cord), and otitis media (ear infection). Importantly, this pathogen has been isolated previously from the crew pre-flight and related bacteria are found in the spacecraft environment. Experiments will be performed to identify and characterize S. pneumoniae genes and proteins, which are differentially expressed in response to the space environment and compare microgravity-induced genes and proteins to those expressed during post-flight animal infection.
This experimental approach will result in new information about a significant human pathogen, add to our knowledge about the S. pneumoniae pathogenic mechanism, and also provide basic information on the bacterial model system of gene and protein expression in the space environment.
S. pneumoniae is a respiratory microbe that is normally found in the upper respiratory tract of approximately 40 percent of the healthy human population. The identification of specific S. pneumoniae virulence factors and cellular and molecular processes may aid scientists in furthering the understanding of how this bacteria causes infection. This data may aid in the design and development of new antimicrobial drugs.
Pre-flight the S. pneumoniae cultures will be grown on the ground in a laboratory environment and inoculated into Todd Hewitt Yeast extract (THY) growth medium for the flight experiment. The bacterial cultures will be loaded into the experiment containers approximately L-72 hours and will be launched at 4 degrees C in the Microgravity Environment Research Locker/INcubator (MERLIN).
Applications
Space Applications
Identification of the global genetic responses undergone by S. pneumoniae in reaction to space will enable this single-flight experiment to determine if the spacecraft environment exerts a selective pressure on microbial contaminants, leading to increased virulence and contributing to increased health risks to the crew. Results from SPEGIS will also provide information on the threat of opportunistic pathogens in the space environment, which will assist in the development of diagnostic tools to monitor the atmosphere and surfaces (air, soil, and food) for the presence of these microbes. Further, identification of spaceflight alterations to genes and proteins involved in bacterial proliferation and mutation will provide targets for pharmacological intervention, which will ultimately facilitate long-term exploration of the Moon and Mars.
Earth ApplicationsAnalyzing and understanding the mechanisms utilized by S. pneumoniae to adapt to microgravity will likely lead to the development of novel methods to combat newly emerging drug-resistant strains, which could greatly assist in disease prevention and management on Earth.
Operations
Operational Requirements
Vials containing bacterial cultures will be loaded into the SPEGIS Canister Assembly. A total of three canisters will be flown on the space shuttle. Each Canister contains three 8 ml polypropylene vials. The vials are inserted into vial jackets to improve contact and enhance thermal transfer. The compression pad eliminates space between the vials and canister lid.
Operational ProtocolsThe SPEGIS payload will be launched while stored at +4 degrees C in the Microgravity Environment Research Locker/INcubator (MERLIN). After the orbiter docks with the ISS, the canisters will be transferred to the Minus Eighty Laboratory Freezer for ISS (MELFI) for +2 degrees C cold stowage. For the on-orbit incubation phase, the canisters will be transferred back to MERLIN and then incubated at +37.5 degrees C. After incubation, the canisters will be transferred back to MELFI for -95 degrees C cryopreservation. The samples will be returned to Earth while stored in the Double Coldbag with ICEPACs at -32 degrees C, which will maintain the integrity of the frozen samples for post-flight analysis by the investigator.
Results/More Information
Information Pending
Related Web Sites
Publications
Results Publications
Related Publications
Images
Scanning Electron Micrograph of Streptococcus pneumoniae (x14,520). Provided by Phillips, D.M., New England Journal of Medicine, 1993 Aug 12; 329(7):477. Image courtesy of NASA, Johnson Space Center.+ View Larger Image
Top view of the SPEGIS sample container, showing the three sample vials. Image courtesy of NASA, Johnson Space Center.+ View Larger Image
SPEGIS sample container, vials and vial jackets. Image courtesy of NASA, Johnson Space Center.+ View Larger Image
NASA Image - S118E06151: STS-118/13A.1 Missions Specialist, Astronaut Barbara Morgan is in the process of transferring the samples for the Streptococcus pneumoniae Expression of Gene in Space (SPEGIS) investigation to the ISS for storage.+ View Larger Image
NASA Image - S118E06158: STS-118/13A.1 Missions Specialist, Astronaut Barbara Morgan is inserting the samples for the SPEGIS investigation into the Minus Eighty-Degree Laboratory Freezer for ISS (MELFI) for storage during the mission.+ View Larger Image
Ames Research Center scientist demonstrate loading bacteria into vials. Photo Credit: NASA Ames Research Center/Dominic Hart.+ View Larger Image
A scientist loads a vial into the SPEGIS canister. In the background, the vials are stored in a four degree C Labtop cooler. Photo Credit: NASA Ames Research Center/Dominic Hart.+ View Larger Image
The assembled SPEGIS canisters are placed into the torque tool. Photo Credit: NASA Ames Research Center/Dominic Hart.+ View Larger Image
Information Provided and Updated by the ISS Program Scientist's Office