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<p class="f14"> Two approaches were used:<br><br> | <p class="f14"> Two approaches were used:<br><br> | ||
− | <b>1. Converting between absorbance of cells to absorbance of a known concentration of beads</b><br> | + | <b>1. Converting between absorbance of cells to absorbance of a known concentration of beads.</b><br> |
Absorbance measurement uses the light scattering by a sample of cells in liquid.The variable in this measurement is the concentration of the cell. With assumption that the silica beads at the size of typical E.coli cells would scatter the light in similar way, the absorbance measurement with known concentration of the beads can be standardized as the “equivalent concentration of beads” measurement. | Absorbance measurement uses the light scattering by a sample of cells in liquid.The variable in this measurement is the concentration of the cell. With assumption that the silica beads at the size of typical E.coli cells would scatter the light in similar way, the absorbance measurement with known concentration of the beads can be standardized as the “equivalent concentration of beads” measurement. | ||
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Revision as of 16:12, 17 October 2018
INTERLAB STUDY
Synthetic biology interconnects the principles of biology and engineering. Reliable and repeatable measurement is one of the fundamentals of engineering, which synthetic biology must also aspire to achieve. However, replicability of fluorescence measurements between labs presents a unique challenge because of differences in how the data are acquired and processed, and other sources of systematic variability that are not accounted for (such as the number of cells in a sample). By using “relative expression” comparisons, users from different labs cannot directly compare results.
The purpose of the 2018 InterLab Study was to attempt to reduce lab-to-lab variability by standardizing green fluorescent protein (GFP) fluorescence measurements. This was done by normalizing GFP fluorescence to absolute cell count or colony-forming units (CFUs) instead of optical density (OD).
Methods
Overview
Two approaches were used:
1. Converting between absorbance of cells to absorbance of a known concentration of beads.
Absorbance measurement uses the light scattering by a sample of cells in liquid.The variable in this measurement is the concentration of the cell. With assumption that the silica beads at the size of typical E.coli cells would scatter the light in similar way, the absorbance measurement with known concentration of the beads can be standardized as the “equivalent concentration of beads” measurement.
2. Counting colony-forming units (CFUs) from the sample.
Simply, growing cells on a plate and counting the number of colonies on the plate can determine the amount of cells in a sample of liquid. The concentration of the sample can be obtained with the number of singly grown cells in the plate, which indicates the amount of cells, and the volume of media that is plated out. The positive and negative control samples will be used to calculate a conversion factor from absorbance to CFU.
For complete methods, refer to: https://2018.igem.org/Measurement/InterLab/Plate_Reader
Our Equipment
A Molecular Devices Spectramax i3x plate reader was used to measure sample absorbance and fluorescence. This device has variable temperature settings, top optics, and pathlength correction, which can be disabled. All GFP measurements were taken at wavelengths of 535/25nm for emission and 485/20nm for excitation. We used clear-bottomed 96-well plates for all measurements.
Calibration
1. LUDOX CL-X (45% colloidal silica suspension) was used as a single point reference to obtain a
conversion factor to transform absorbance data into a comparable OD measurement.
2. A dilution series of monodisperse silica microspheres was used to measure absorbance and produce a standard curve of particle concentration. The size and optical characteristics of these microspheres are similar to cells and there is a known amount of particles per volume. This standard curve was later used to convert absorbance measurements to an estimated number of cells.
3. A dilution series of fluorescein, which has similar excitation and emission properties to GFP, was used to generate a fluorescein standard curve. This standard curve was later used to convert
Cell-based readings to an equivalent fluorescein concentration.
Cell Measurement Protocol
Measured...
Testing Devices
The negative control did not contain fluorescent DNA parts and positive control is the fluorescent beads with known value. From the fluorescence values of two controls, the fluorescence value of each devices were calculated. Additionally, the kit plate and well locations were also pre-determined to minimize the detecting errors between trials.
Device | Pert number | Plate | Location |
---|---|---|---|
Negative Control | BBa_R0040 | Kit Plate 7 | Well 2D |
Positive Control | BBa_I20270 | Kit Plate 7 | Well 2B |
Test Device 1 | BBa_J364000 | Kit Plate 7 | Well 2F |
Test Device 2 | BBa_J364001 | Kit Plate 7 | Well 2H |
Test Device 3 | BBa_J364002 | Kit Plate 7 | Well 2J |
Test Device 4 | BBa_J364007 | Kit Plate 7 | Well 2L |
Test Device 5 | BBa_J364008 | Kit Plate 7 | Well 2N |
Test Device 6 | BBa_J364009 | Kit Plate 7 | Well 2P |
Results
We expected a linear relationship between concentration and fluorescence/absorbance. However, the log-scale particle standard curve (Figure 2B) does not exhibit a linear relationship. Possible sources of error include pipetting error or oversaturation of the detector.
The conversion of average fluorescence to reference unit was designed to reduce the impact of unorganized unit system.
For fluorescence to OD conversion, fluorescence was converted to absorbance and to OD.
For fluorescence to particle conversion, Molecules of Equivalent of Fluorescence (MEFL) was converted to absorbance and to particles.
The trend showed that except device 3, all other devices contained fluorescence part and the device 2 and 5 had increased fluorescence part after 6 hours, but device 1,4, and 6 had decreased fluorescence part after 6 hours.
Fluorescein Standard Curve
Fluorescein standard curve
Fluorescein standard curve (log scale)
Particle Standard Curve
Standard curve of particles
Standard curve of particles (log scale)
Average Fluorescence
Average fluorescence per OD
Average fluorescence per particle