Team:DTU-Denmark/Interlab form
From 2014.igem.org
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class=SpellE>BioLector</span> was instructed to take measurements every 4.86 | class=SpellE>BioLector</span> was instructed to take measurements every 4.86 | ||
minutes. Settings: GFP: 80; Biomass: 30; Humidity: controlled at 95%. <span | minutes. Settings: GFP: 80; Biomass: 30; Humidity: controlled at 95%. <span | ||
- | class=GramE> | + | class=GramE>1.5 mL LB <span class=SpellE>media</span> with relevant antibiotics |
in each well.</span><o:p></o:p></span></p> | in each well.</span><o:p></o:p></span></p> | ||
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</table> | </table> | ||
</br> | </br> | ||
- | <img src="https://static.igem.org/mediawiki/2014/c/c2/DTU-Denmark_BioLector_Interlab_chart.png" width=" | + | <img src="https://static.igem.org/mediawiki/2014/c/c2/DTU-Denmark_BioLector_Interlab_chart.png" width="900" /> |
<p> | <p> | ||
The background-subtracted values were calculated by subtracting the mean of E0240 from the other means. | The background-subtracted values were calculated by subtracting the mean of E0240 from the other means. |
Latest revision as of 07:43, 24 September 2014
For each assay
that you perform, fill out the following worksheet. Answer each question with
enough detail to allow another person to replicate your measurements without
needing to ask you any questions. This does not necessarily mean you need to
describe everything in detail---for example, if you use a standard assay, you
just need to give enough information to allow another person to use that assay
in the same way that you did.
Section I: Provenance & Release
Who did the actual work to acquire these measurements?
Our laboratory
group carried out the experiments this group consists of Anne Sofie Lærke
Hansen, Anne Pihl Bali, Caroline Mosbech, Kristian Barreth Karlsen, Kristian Jensen
& Rasmus Bech
What other people should be credited for these measurements?
We did all the
experimental work for the interlab study ourselves.
Ali Altintas assisted us in setting up the BioLector.
Anne Egholm helped us to use the Flow Cytometer.
On what dates were the protocols run and the measurements taken?
The BioLector experiment ran: 10th-11th of September 2014
The Flow
cytometry experiment was done on the 22nd of September 2014.
Do all persons involved consent to the inclusion of this data in
publications derived from the iGEM interlab study?
Yes.
Section II: Protocols
What protocol did you use to prepare samples for measurement?
Construct
strains:
Create
multiple strains expressing GFP from different promoters from the Andersen
Library. Constructs were prepared with Standard Assembly. (see
protocol).
Plasmid
were purified with Zyppy™
Plasmid Miniprep Kit from Zymo
research following manufacturer's protocol.
Competent
DH5α cells were prepared (see protocol).
Purified
plasmids were transformed into competent DH5α cells (see protocol).
Culture
measurements:
We used cell
culture tubes (10 mL) containing 2 mL LB medium (with 0.5% NaCl)
and 25 μg/mL
chloramphenicol for each strain. To each of the tubes, we inoculated cells from
a single colony with a sterile inoculation loop and left it overnight at
37°C, shaking at 350 rpm.
The wells of
the sterile BioLector plate (48 well FlowerPlate) was prepared with 1450 μL (1500μL for controls)
of LB (0.5% NaCl) containing 25 μg/mL chloramphenicol. The following day we transferred
10 μL of each culture
into an Eppendorf tube with 990 μL of sterile
physiological salt water (creating a 100-fold dilution). We inoculated the
individual BioLector wells with 10 μL of the dilution (creating an
additional 150-fold dilution). Each strain was grown in triplicates to make
sure we had 3 independent measurements and a more precise result. We incubated
the plate in the BioLector at 37°C and 1000 rpm for 12.5 hours (stationary phase was
reached). During the growth experiment we measured biomass and GFP fluorescence
every 5 minutes. Biomass was measured by light scatter at 620 nm, while
fluorescence was measured at 520 nm, with an excitation wavelength of 488 nm.
Single cell
measurements:
2 mL LB (0.5% NaCl) was inoculated with cells from a plate and grown
overnight.
The cultures
were washed and resuspended in PBS.
The cell
suspensions were diluted in PBS to a concentration where the flow cytometer
could detect 1000-1500 events per second.
What sort of instrument did you use to acquire measurements?
What
is the model and manufacturer?
Instrument: BioLector (Basic) - Microbioreactor
System; Manufacturer: m2p-laps.
Instrument: FACSCalibur Cell Analyzer; Manufacturer: BD Biosciences
How
is it configured for your measurements?
The BioLector is fitted with filters for measuring biomass
(scatter at 620 nm) and GFP (emission at 520 nm, excitation with 488 nm). Settings:
Gain: GFP: 80; Biomass: 30; Humidity: controlled at 95%; Shake:
1000 rpm.
The FACSCalibur was set up with a side scatter threshold of 4.5, to filter out events that were likely to be noise. Fluorescence was measured with a log amplification value of 750.
What protocol
did you use to take measurements?
The BioLector was instructed to take measurements every 4.86
minutes. Settings: GFP: 80; Biomass: 30; Humidity: controlled at 95%. 1.5 mL LB media with relevant antibiotics
in each well.
The FACS was
set up with a threshold on side scatter, as events with low side-scatter are
very likely noise, i.e. not actual cells. Each sample was then analysed at 1000-1500 events per second, until a total of
100,000 events was reached.
What method is
used to determine whether to include or exclude each sample from the data set?
Strains that
showed correct digest patterns were included. Strains that were sequenced and
showed wrong sequences were excluded. As were cultures that did not grow, and
single replicates that showed negligible fluorescence.
What exactly
were the controls that you used?
DH5α with BBa_E0240 (no promoter) was used
to determine cell background fluorescence (without GFP). For the BioLector, clean media (without cells) was used to
determine media fluorescence.
What
quantities were measured?
On the BioLector: GFP
fluorescence (488 nm /520 nm) and biomass (scatter at 620nm). The flow
cytometer measured forward scatter (cell size), side scatter (cell granularity)
and fluorescence.
How much time did it take to acquire each set of measurements?
The running time of the BioLector
experiment was 12 hours and 30 minutes. One cycle took 4.86 min.
Flow
cytometry: The measurements themselves took less than 1 hour.
How much does it cost to acquire a set of measurements?
Assuming the lab already have
a BioLector. For
a full plate with samples: Flowerplate for the BioLector, 170mL LB medium, chloramphenicol, 16 pts. inoculation tubes, tips, Eppendorf tubes approximately $150.
What are the practical limits on the number or rate of measurements
taken with this instrument and protocol?
BioLector: With
the used protocol 48 samples can be measured within short intervals of time,
however, 3 of these should be used as control. So when measuring triplicates it
is possible to measure 15 different strains in the protocol used for the interlab study. Analysing such a
plate takes approximately 12 hours.
Section III: Measured Quantities
For each type of quantity measured, report on the following:
What are the
units of the measurement?
All
measurements are in arbitrary units in both the BioLector
and the FACSCalibur.
What is the
equivalent unit expressed as a combination of the seven SI base units?
Not applicable
due to arbitrary units.
Precision:
What is the
range of possible measured values for this quantity, using your instrument as
configured for these measurements?
According to the manufacturer, the BioLector has a linear range for OD600 from 0.2 to
600.
What are the
significant figures for these measurements?
We have fitted a mixed model with promoters as a fixed
effect and replicates as a random effect. This model gave a residual
standard deviation on fluorescence/OD of 0.040. With this result we can say that a single fluorescence/OD
measurement is no more precise than the measured value ± 0.040.
Is the
precision the same across the entire range? If not, how does it differ?
We have no data to determine if the precision differ
through the entire range.
Accuracy:
When was the instrument last calibrated?
The machine “self-calibrate”
before every cycle, meaning the BioLector sensor/probe
returns to the original position and measure a fixed known light intensity. It
is approximately 5 years old but the filters have been changed 3 years ago.
How was the
instrument calibrated?
The machine “self-calibrate” before every cycle,
meaning the BioLector sensor/probe returns to the
original position and measure a fixed known light intensity.
Section IV: Measurements
BioLector experiment
For each sample, report:
The following table shows the BioMass and Fluorescence measurements acquired from the BioLector. Each entry in the table is the mean value of all the measurements taken during a 3-hour period, with 4.88 min intervals. The full dataset can be found here.
Name |
Biomass |
GFP
fluorescence |
Fluorescence/OD |
Note |
J23100-1 |
12.59 |
2.13 |
0.1695 |
Excluded |
J23101-1 |
54.80 |
30.17 |
0.5506 |
|
J23102-1 |
33.43 |
1.27 |
0.0381 |
Excluded |
J23103-1 |
62.60 |
0.38 |
0.0061 |
|
J23106-1 |
59.10 |
30.66 |
0.5188 |
|
J23107-1 |
60.78 |
13.95 |
0.2296 |
|
J23100-2 |
57.97 |
47.45 |
0.8185 |
|
J23101-2 |
59.11 |
31.42 |
0.5315 |
|
J23102-2 |
61.60 |
18.93 |
0.3073 |
|
J23103-2 |
65.37 |
0.42 |
0.0064 |
|
J23106-2 |
59.04 |
30.29 |
0.5130 |
|
J23107-2 |
60.63 |
13.82 |
0.2279 |
|
J23100-3 |
61.51 |
49.65 |
0.8072 |
|
J23101-3 |
60.83 |
32.54 |
0.5349 |
|
J23102-3 |
61.59 |
21.08 |
0.3422 |
|
J23103-3 |
65.75 |
0.39 |
0.0060 |
|
J23106-3 |
59.63 |
29.42 |
0.4934 |
|
J23107-3 |
60.89 |
13.89 |
0.2280 |
|
J23113-1 |
69.70 |
0.43 |
0.0062 |
|
J23114-1 |
69.60 |
1.56 |
0.0225 |
|
J23115-1 |
66.27 |
1.85 |
0.0279 |
|
J23118-1 |
50.75 |
95.47 |
1.8811 |
|
J23119-1 |
46.99 |
17.50 |
0.3724 |
|
No
promoter-1 |
64.81 |
0.39 |
0.0060 |
|
I20260-1 |
61.36 |
19.75 |
0.3219 |
|
J23113-2 |
72.55 |
0.45 |
0.0062 |
|
J23114-2 |
71.19 |
1.58 |
0.0223 |
|
J23115-2 |
68.07 |
1.88 |
0.0276 |
|
J23118-2 |
50.15 |
92.32 |
1.8410 |
|
J23119-2 |
47.35 |
17.18 |
0.3629 |
|
No
promoter-2 |
67.06 |
0.38 |
0.0057 |
|
I20260-2 |
62.79 |
18.62 |
0.2966 |
|
J23113-3 |
77.21 |
0.43 |
0.0056 |
|
J23114-3 |
76.52 |
1.63 |
0.0213 |
|
J23115-3 |
72.29 |
1.92 |
0.0265 |
|
J23118-3 |
52.00 |
96.50 |
1.8556 |
|
J23119-3 |
47.13 |
16.81 |
0.3567 |
|
No
promoter-3 |
70.07 |
0.39 |
0.0056 |
|
I20260-3 |
64.47 |
17.33 |
0.2688 |
For each group of replicates, report:
The data was analyzed by fitting a statistical mixed model to the data, using the lmerTest package in R. The different promoters were modeled as a fixed effect, and replicates were modeled as a random effect. The estimated means for each promoter and the standard error of the mean can be seen in the table and chart below.
Strain |
Mean |
Standard
Error |
Background-subtracted mean |
J23100 |
0.91 |
0.01300 |
0.9050 |
J23101 |
0.61 |
0.01160 |
0.5980 |
J23102 |
0.37 |
0.01300 |
0.3610 |
J23103 |
0.01 |
0.01160 |
0.0005 |
J23106 |
0.58 |
0.01160 |
0.5690 |
J23107 |
0.26 |
0.01160 |
0.2500 |
J23113 |
0.01 |
0.01160 |
0.0003 |
J23114 |
0.03 |
0.01160 |
0.0183 |
J23115 |
0.03 |
0.01160 |
0.0243 |
J23118 |
2.14 |
0.01160 |
2.1300 |
J23119 |
0.42 |
0.01160 |
0.4120 |
I20260 |
0.32 |
0.01160 |
0.3080 |
E0240 |
0.0079 |
0.00821 |
The background-subtracted values were calculated by subtracting the mean of E0240 from the other means.
The replicate standard deviation was estimated to be 0.014, meaning that the effect of using multiple replicates contributes a random effect distributed with this standard deviation. The residual standard deviation was estimated to be 0.040, meaning that the random effect of taking multiple measurements on the same sample has this standard deviation.
Which, if any,
of the samples are excluded and why
In two of the
triplicate sets, one outlier was excluded: For the promoter J23100, one
replicate did not grow very much. For promoter J23102 one replicate had negligible
fluorescence.
Flow cytometry
Histograms of fluorescence values for each construct are shown below. At least 100,000 cells were measured for each construct. Values on the X-axes are log10-values of the fluorescence measurements. For each construct, a threshold was determined to split the measurements into high-fluorescence and low-fluorescence cells. The high-fluorescence sub-datasets were log10-transformed and a normal distribution was fitted. Mean and standard deviation for the log-normal distributions are reported below each histogram. The vertical red line indicates the threshold.
Mean: 2.41 SD: 0.25
Mean: 1.02 SD: 0.27
Mean: 3.05 SD: 0.24
Mean: 2.32 SD: 0.48
Mean: 2.33 SD: 0.20