BerkiGEM2007Present2
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<h1 align="center">Freeze-Drying Device</h1> | <h1 align="center">Freeze-Drying Device</h1> | ||
- | <p align="justify">Bactoblood needs the ability to be stored for long periods in a freeze-dried form so that it can be stockpiled and easily transported. We therefore sought a genetic device that could improve the Bactoblood's structural integrity during dessication. We designed two distinct desiccation devices: one that utilizes the disaccharide trehalose and one that involves the small molecule hydroxyectoine. The figure below shows our freeze dried Bactoblood. The white chunks are crystallized sucrose. </p> | + | <p align="justify">Bactoblood needs the ability to be stored for long periods in a freeze-dried form so that it can be stockpiled and easily transported. We therefore sought a genetic device that could improve the Bactoblood's structural integrity during dessication. We designed two distinct desiccation devices: one that utilizes the disaccharide trehalose and one that involves the small molecule hydroxyectoine. The figure below shows our <strong>actual freeze dried Bactoblood</strong>. The white chunks are crystallized sucrose. </p> |
<p align="center"><img src="https://static.igem.org/mediawiki/2007/6/60/FDequation.jpg" width="777" height="533" alt=""></p> | <p align="center"><img src="https://static.igem.org/mediawiki/2007/6/60/FDequation.jpg" width="777" height="533" alt=""></p> | ||
<h2 align="center">Trehalose</h2> | <h2 align="center">Trehalose</h2> |
Revision as of 01:45, 27 October 2007
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Freeze-Drying Device
Bactoblood needs the ability to be stored for long periods in a freeze-dried form so that it can be stockpiled and easily transported. We therefore sought a genetic device that could improve the Bactoblood's structural integrity during dessication. We designed two distinct desiccation devices: one that utilizes the disaccharide trehalose and one that involves the small molecule hydroxyectoine. The figure below shows our actual freeze dried Bactoblood. The white chunks are crystallized sucrose.
Trehalose
The genes in the trehalose biosynthesis pathway are pulled right out of the E.coli genome and consist of otsA and otsB. By overexpressing these genes after bactoblood has reached saturation, the can protect itself from damage during freeze drying without having to add exogenous protectants. OtsB encodes for a 29.1-kDa trehalose-6-phosphate phosphatase and otsA encodes for a 53.6-kDa trehalose-6-phosphate synthase. Together they make up a trehalose-6-phosphate synthase/phosphatase complex. Naturally, the 3' end of the otsB coding region overlaps the 5' end of the otsA coding region by 23 nucleotides. The Trehalose helps the frozen dehydrated cells to recover back to a functioning hydrated state. Not all cells survive the freeze drying process but Trehalose increases the rate of success.
Hydroxyectoine
The hydroxyectoine biosynthesis pathway present in Streptomyces Chrysomallus consists of four genes: thpA, thpB, thpC and thpD. In our system, we plan on The other three genes are there to initiate the process. When inserted into a bacterium, hydroxyectoine will prevent dessication and many other extremes. It will protect the bacteria's proteins and cell membrane.
Lyophilization
The image above demonstrates that trehalose stabilizes the cell's lipid membrane and prevents leakage upon rehydration.
References
P. Louis et al, "Survival of Escherichia coli during drying and storage in the presence of compatible solutes", Appl. Microbiol Biotechnol., 41:684-688, 1994
MAximino Manzanera et al., "High survival and stability rates of Escherichia coli dried in hydroxyectoine", FEMS Microbiology Letters, Vol. 223, Issue 2. pp. 347-352, 2004
Georg Lentzen and Thomas Schwarz, "Extremolytes: natural compounds from extremophiles for versatile applications", Applied Microbiology and Biotechnology, Vol 72, No. 4, 2006
Julia Prabhu et al., "Functional Expression of the Extoine Hydrozylase Gene (thpD) from Streptomyces chrysomallus in Halomonas elongata", Applied and Environmental Mircobiology, vol. 70, No. 5, p. 3130-3132, 2004
SB Leslie et al, "Trehalose and sucrose protech both membranes and proteins in intact bacteria during drying", Appl. Environmental Biology, vol. 61, No. 10, 3592-3597, 1005
I Kaasen et al, "Molecular cloning and physical mapping of the otsBA genes, which encode the osmoregulatory trehalose pathway of Escherichia coli: evidence that transcription is activated by katF (AppR), J. Bacteriology, 174(3): 889-898, 1992
Strom AR and Kaasen I, "Trehalose metabolism in Escherichia coli: stress protection and stress regulation of gene expression", Mol. Microbiol. 8(2): 205-10, 1993
W Boos et al. "Trehalose of Escherichia coli. Mapping and cloning of its structural gene and identification of the enzyme as a periplasmid protein induced under high osmolarity growth conditions.", J. Biol. Chem, Vol. 262, Issue 27, 13212-13218, 09, 1987.
<<< Return to UC Berkeley iGEM 2007
<<Previous Section: Growth Control | Next Section: Human Practices>>