Search Results

It is hypothesized that the weightless environment experienced during space flight has a stimulating effect on the growth rate of microorganisms. This theory was tested with the bacterium Escherichia coli using protocols and supporting hardware evolved over five space shuttle missions between April, 1991 and July, 1993. In comparing 38 bacterial growth experiments across multiple flights, the overall average population density of E. coli achieved in space was 88% greater than that of matched ground controls (N=19 flight, 19 ground, p < 0.05). Depending on test variables, growth increases in space of up to 257% over ground controls were observed. Analysis of bacterial proteins by gel electrophoresis indicated an apparent difference in expressed protein between flight and ground control E. coli samples in the range of 20-30 kD.

Plant growth, and especially plant performance experiments in microgravity are limited by the currently available plant growth facilities (low light levels, inadequate nutrient delivery and atmosphere conditioning systems, insufficient science instrumentation, infrequent flight opportunities). In addition, mission durations of 10 to 14 days aboard the NSTS Space Shuttle allow for only brief periods of microgravity exposure with respect to the life cycle of a plant. Based on seed germination experiments (5 missions from 1992 - 1994), using the Generic BioProcessing Apparatus hardware (GBA), two new payloads have been designed specifically for plant growth. These payloads provide new opportunities for plant gravitational and space biology research and emphasize the investigation of plant performance (photosynthesis, biomass accumulation) in microgravity.