Buildups of significant numbers of microorganisms during space travel can cause disease and other problems such as corrosion. Moreover, the effect of long-term exposure of microorganisms to high radiation levels and weightlessness is unknown, but there is evidence that organisms under these conditions may exhibit altered properties that could affect their pathogenicity and/or sensitivity to antibiotics. A team headed by Dr. George E. Fox is developing in-flight systems to monitor microbial populations in space to ensure the quality of spacecraft air and water. Fox is also studying the effects of weightlessness on microorganisms. This research will lead to an alternate identification system that will not only test for organisms that are known to be problematic but would also identify the genetic affinity of an unknown microorganism that proves to be problematic. This research will provide the means to understand microbial ecosystems in the space environment and lead to a detection system for harmful microorganisms that can be used in space and on Earth.
Overview
Microorganisms in the Spacecraft Environment
Principal Investigator:
George E. Fox, Ph.D.
Organization:
University of Houston
Technical Summary
An effective set of probes may have utility in a large variety of formats. It is likely that actual implementation in space flight will be driven by mission instrumentation capabilities. Although there is considerable interested in development of array-based instruments other approaches may be preferable, especially for International Space Station applications. We therefore have focused attention on several alternative formats as well. In this regard, several probes for organisms of primary interest have been successfully implemented in a molecular beacon format. Homogenous solution assays of this type would require minimal sample processing and could be readily conducted by astronauts in flight with results signaled by the presence or absence of color changes. It was found that "red-shifted" beacons have minimal contributions from sample autofluorescence. In addition, we demonstrated the potential utility of fluorescent nucleotides such as 2-aminopurine in molecular beacon applications. Efforts were also initiated late in Year 2 to assess the possibilityof identifying signature oligonucleotides with mass spectrometry.
Regardless of the assay system ultimately chosen, rapid and simplified systems for sample processing in space will be required. During the past year, we provided further evidence that RNA/DNA purification using compaction agents eliminates the need for preprocessing steps and that the same agents can be used to enhance the adsorption capacity of anion exchangers. Also in the past year we developed further evidence that immobilized metal affinity chromatography (IMAC) which is widely used with proteins is also effective with nucleic acids. Most recently, we have begun to look at novel ways of obtaining rapid final purification of specific RNAs such as 16S rRNA.
There is preliminary evidence that the microgravity environment seen in space effects bacteria in non-obvious ways with such possible outcomes as altered drug resistance or pathogenicity. In order to explore this possibility further, we are examining the response of E. coli cells grown in simulated microgravity. In order to do this, we are using modern proteomics technology to examine the expression levels of each and every gene in E. coli when cells are grown in a low shear modeled microgravity (LSMGG) environment. Various kinetic controls have been completed and initial hybridizations with organisms grown under simulated microgravity have been made. These initial studies point to several interesting clusters of genes that appear to be part of a specific response to the LSMMG. In the coming year, we will complete replicates of these initial experiments and examine the results in a multiorganism context.
Overall, Year 2 of the project was very productive. During the past year, four-peer review papers were published, three more are in press, and five additional papers have been submitted. In addition, a book chapter is in press.