Difference between revisions of "Real-time RNA profiling within a single bacterium"
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In short, the authors first show that their FCS data matches that of the current gold standard technique (260 nm UV absorption), after which they go on to demonstrate a few interesting findings. For example, they found that while the RNA levels of individual cells vary significantly over time, the averaging of several cells reduces this noise (Figure 1), explaining why such variation has gone largely unnoticed within the scientific community. | In short, the authors first show that their FCS data matches that of the current gold standard technique (260 nm UV absorption), after which they go on to demonstrate a few interesting findings. For example, they found that while the RNA levels of individual cells vary significantly over time, the averaging of several cells reduces this noise (Figure 1), explaining why such variation has gone largely unnoticed within the scientific community. | ||
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+ | ==Soft matter example== | ||
+ | While this paper had no mention of wetting, surfaces, or capillary forces, the technique of fluorescence correlation spectroscopy is probably worth mentioning, as it is employed specifically in soft matter experiments. FCS is typically used to measure diffusion constants of fluorescent molecules in solution. |
Revision as of 02:57, 2 May 2009
Zach Wissner-Gross (May 1, 2009)
Information
Real-time RNA profiling within a single bacterium
Thuc T. Le, Sebastien Harlepp, Calin C. Guet, Kimberly Dittmar, Thierry Emonet, Tao Pan, Philippe Cluzel
PNAS, 2005, 102, 9160-9164
Soft matter keywords
Diffusion, fluorescence correlation spectroscopy
Summary
While every cell in an organism has essentially the same genetic code, cell morphology and behavior vary due to which genes are expressed. Studying intracellular RNA or protein levels represents a common method for studying changes in cell behavior. However, classical methods for for observing temporal changes in these intracellular concentrations require lysing cells at different time points.
Cluzel and coworkers offer a different approach that both yields single-cell resolution and is real-time (the authors estimate their acquisition time to be 2 seconds), without noticeably affecting the cell during the observation. Using a high-NA objective, the authors focus a blue laser beam to a diffraction-limited spot inside the bacterium, and then perform fluorescence correlation spectroscopy (FCS), which I explain below in more detail.
In short, the authors first show that their FCS data matches that of the current gold standard technique (260 nm UV absorption), after which they go on to demonstrate a few interesting findings. For example, they found that while the RNA levels of individual cells vary significantly over time, the averaging of several cells reduces this noise (Figure 1), explaining why such variation has gone largely unnoticed within the scientific community.
Soft matter example
While this paper had no mention of wetting, surfaces, or capillary forces, the technique of fluorescence correlation spectroscopy is probably worth mentioning, as it is employed specifically in soft matter experiments. FCS is typically used to measure diffusion constants of fluorescent molecules in solution.