Gregg Randolph Linda van Diepen Alex Buerkle
This experiment is being repeated due to some errors that occurred in processing during the initial platesexperiment.
Experiment protocol below is not finalized.
Questions:
How can we best accommodate low concentration input DNAs?
Concentrate input DNAs?
Concentrate/normalize low yield products?
Both?
Just put more volume of original DNA in?
In the sequence yield, does input concentration, substrate, or some other factor correlate well with low read counts?
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Pull aliquots of some high read count and low read count samples. (New Pending new low read samples requested).
Quantify all samples not including blanks or mock community.
For previously low yielding samples, repeat at typical template amount, and at 2x, and 4x volume added to the reaction (in column 2,3,4, and 6, 7, 8). 6x8 samples in low yield, 8 in high yield, 8 of mock community, 8 of blank (ISD only). 72 reactions with different templates. See template below for clarification.
Template layout is replicated/duplicated, with different barcodes for duplicates.
1 set of 36 products will not be adjusted for pooling.
1 set of 36 will be adjusted for pooling per qPCR results.
Use ISD at lower than typical concentrations for all for PCRs, as a positive internal control and recognizing that this will wreck reconstruction of absolute counts. Will add ISD to master mix.
Treat templates with previously high read counts in standard manner, except for lower concentration ISD.
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NOTE: Water in the master mix has been adjusted to a lower amount. The plate set up below will replace the water usually added to the master mix while also observing showing if a decrease in water and an increase in template will increase PCR yields.
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Make 1:1000 dilutions of all samples from the PCR plates by adding 1 ul to 999 ul TE in a deep well plate:
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
A |
Tube 127 | mock community | blank with ISD only |
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| NTC | |||||||
B |
Tube 73 | mock community | blank with ISD only |
| 04.0002 pM Std | 0.0002 pM Std | |||||||
C |
PLT1: G3 | mock community | blank with ISD only |
| 0.002 pM Std | 0.002 pM Std | |||||||
D |
PLT1: F7 | mock community | blank with ISD only |
| 0.02 pM Std | 0.02 pM Std | |||||||
E | blank with ISD only |
Tube 127 | mock community | blank with ISD only |
| 0.2 pM Std | 0.2 pM Std | ||||||
F |
Tube 73 | mock community | blank with ISD only |
| 2 pM Std | 2 pM Std | |||||||
G |
PLT1: G3 | mock community | blank with ISD only |
| 20 pM Std | 20 pM Std | |||||||
H |
PLT1: F7 | mock community | blank with ISD only |
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Add 16 ul of Illumina Library Quantification MasterMix to each well:
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Add 4 ul of template, pool, or standards to each well:
Sample
qPCR Result
(nanomoles)
Quantity in sample (39uL)
(nanomoles)
Elution volume post SpeedVac
(uL)
Quantity post SpeedVac
(nanomoles)
Amount to add to pool
(uL)
Quantity in final pool
(nanomoles)
SAG192203_R (E1)
0.273
10.65
10
41.52
2.4
10
SAG_S43P4R_R (E4)
0.0411
1.60
4
15.36
2.6
10
SAG_S13P3R_R (E8)
0.000475
0.02
10
0.08
5
0.04
BLANK_ISD (E9)
0.215
8.39
10
32.71
3.1
10
SAG191508_R (F1)
1.58
61.62
6.3
10
SAG_S10P4R_R (F4)
0.291
11.35
10
44.25
2.3
10
SAG_S3P2R_R (F8)
0.673
26.25
20
51.17
3.9
10
BLANK_ISD (F9)
0.445
17.36
20
33.84
5.9
10
SAG_S14P3R_R (G3)
0.218
8.50
10
33.14
3.0
10
SAG_S14P3R_R (G4)
0.00121
0.05
10
.19
5
0.095
SAG190267_R (G8)
0.0154
0.60
4
5.76
2
2.88
SAG191507_R (H3)
0.000115
0.004
10
.02
5
0.01
SAG191507_R (H4)
0.00247
0.10
10
0.39
5
0.195
Mock_Comm_R (H5)
0.148
5.77
10
22.50
4.4
10
SAG190430_R (H6)
0.127
4.95
10
19.30
5.2
10
SAG190430_R (H7)
0.00073
0.03
10
.12
5
0.06
SAG190430_R (H8)
0.000326
0.01
10
.04
5
0.02
BLANK_ISD (H9)
0.00311
0.12
10
.47
5
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | ||||||||||||||||||||
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A |
Tube 127 |
PLT2: E11 |
PLT2: E11 |
PLT2: E11 | mock community |
PLT2: A1 |
PLT2: A1 |
PLT2: A1 | blank with ISD only | NTC | NTC | NTC | B |
Tube 73 |
PLT1: H2 |
PLT1: H2 |
PLT1: H2 | mock community |
PLT1: B1 |
PLT1: B1 |
PLT1: B1 | blank mock community | blank with ISD only | NTC | NTC | NTC | ||||||
B |
Tube 73 | mock community | blank with ISD only | 0.0002 pM Std | 0.0002 pM Std | 0.0002 pM Std | ||||||||||||||||||||||||||
C |
PLT1: G3 | mock community | blank with ISD only | 0.002 pM Std | 0.002 pM Std | 0.002 pM Std | ||||||||||||||||||||||||||
D |
PLT1: F7 | mock community | blank with ISD only | 0.02 pM Std | 0.02 pM Std | 0.02 pM Std | ||||||||||||||||||||||||||
E |
Tube 127 | mock community | blank with ISD only | 0.0002 2 pM Std | 0.0002 2 pM Std | 0.0002 2 pM Std | ||||||||||||||||||||||||||
CF |
PLT1: G3 |
PLT2: E1 |
PLT2: E1 |
PLT2: E1 | mock community |
Tube 259 |
Tube 259 |
Tube 73 | mock community | blank with ISD only | 2 pM Std | 2 pM Std | 2 pM Std | |||||||||||||||||||
G |
PLT1: G3 | mock community | blank with ISD only | 0.002 20 pM Std0.002 | 20 pM Std | 0.002 20 pM Std | ||||||||||||||||||||||||||
DH |
PLT1: F7 |
Tube 74 |
Tube 74 |
Tube 74 | mock community |
Tube 10 |
Tube 10 | mock community | blank with ISD only | 0.02 pM Std | 0.02 pM Std | 0.02 pM Std | ||||||||||||||||||||
E |
Tube 127 |
PLT2: E11 |
PLT2: E11 |
PLT2: E11 | mock community |
PLT2: A1 |
PLT2: A1 |
PLT2: A1 | blank with ISD only | 0.2 pM Std | 0.2 pM Std | 0.2 pM Std | ||||||||||||||||||||
F |
Tube 73 |
PLT1: H2 |
PLT1: H2 |
PLT1: H2 | mock community |
PLT1: B1 |
PLT1: B1 |
PLT1: B1 | blank with ISD only | 2 pM Std | 2 pM Std | 2 pM Std | ||||||||||||||||||||
G |
PLT1: G3 |
PLT2: E1 |
PLT2: E1 |
PLT2: E1 | mock community |
Tube 259 |
Tube 259 |
Tube 259 | blank with ISD only | 20 pM Std | 20 pM Std | 20 pM Std | ||||||||||||||||||||
H |
PLT1: F7 |
Tube 74 |
Tube 74 |
Tube 74 | mock community |
Tube 10 |
Tube 10 |
Tube 10 | blank with ISD only |
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Results:
Pool all samples:
Blue samples (top half of plate) will be pooled at 1* ul per sample.
*The original experimental design was to add 2uL per sample for the blue pool but with the extremely low yields occurring in the red half of the plate I reduced the pooling amount of the blue pool to make the two pools closer in total concentration.
Red samples (bottom half) will either just be pooled per qPCR numbers or concentrated via SpeedVac, reconstituted to a higher concentration, and pooled by qPCR results.
NOTE: Row H showed significantly lower yields. I believe this could have occurred due to evaporation of the PCR master mix. The master mix was prepared ahead of time, plated, and refrigerated until samples could be loaded. We prepare master mix plates ahead of time often, with no noticeable evaporation, but I did notice a slight decrease in volume on the outer edges of the plate during sample loading. Due to the master mix being specialized for this experiment, I proceeded with the plates as is since they were in duplicate. If the following steps below do not show the desired result, we could repeat the experiment with the master mix preparation and sample loading occurring on the same day.
Calculations for Red Pool:
Since the majority of the samples in the red pool were in the 10-99 nanomole range, the following samples will be added in higher quantities to ensure the samples are pooled in the same order of magnitude:
In theory, if you decrease the elution volume by 50%, the DNA concentration should increase by 50%. That being said, in order for some of the samples to reach the desired concentration, we will need to vacuum concentrate and resuspend at a lower elution volume.
samples with concentrations between 10-99 will have 1uL added to the pool.
samples highlighted in red were too low to normalize to 10 nanomoles so I just resuspended them at 10uL and used half to at least increase the input quantity.
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Results:
Pool all samples:
Blue samples (top half of plate) will be pooled at 1* ul per sample.
Red samples (bottom half) will either just be pooled per qPCR numbers or concentrated via SpeedVac, reconstituted to a higher concentration, and pooled by qPCR results. (Pending method instructions).
qPCR blue/red pools:
Make 1:1000 dilutions of blue and red pools by adding 1 ul to 999 ul TE in a 1.5mL tubes.
Run each pool in triplicate.
Add 16 ul of Illumina Library Quantification MasterMix to each well:
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Add 4 ul of template, pool, or standards to each well:
| 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 |
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A | LRLR2_Blue_Pool |
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| NTC | NTC | NTC |
B | LRLR2_Blue_Pool |
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| 0.0002 pM Std | 0.0002 pM Std | 0.0002 pM Std |
C | LRLR2_Blue_Pool |
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| 0.002 pM Std | 0.002 pM Std | 0.002 pM Std |
D | LRLR2_Red_Pool |
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| 0.02 pM Std | 0.02 pM Std | 0.02 pM Std |
E | LRLR2_Red_Pool |
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| 0.2 pM Std | 0.2 pM Std | 0.2 pM Std |
F | LRLR2_Red_Pool |
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| 2 pM Std | 2 pM Std | 2 pM Std |
G |
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| 20 pM Std | 20 pM Std | 20 pM Std |
H |
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Results:
Average Results:
LRLR2_Blue_Pool: 18.10 nanomoles
LRLR2_Red_Pool: 8.36 nanomoles
iSeq Run
Dilute to 1 nM based off qPCR results. qPCR results are in pM, but 1:1000 dilution used. The results are effectively in nM for pool.
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pool
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Blue Pool
5001000/Results = ul of Pool to Add
500/18.1= 27.5 1000/____= ____ uL of Pool to Add
5001000- ul of Pool to Add = ul of “10 mM Tris 8.5” to Add
500- 27.5 = 472.5 1000- ____ = ____ uL of 10mM Tris 8.5
Red Pool
5001000/Results = ul of Pool to Add
500/8.36 = 59.8 1000/___ = ___ uL of Pool to Add
5001000- ul of Pool to Add = ul of “10 mM Tris 8.5” to Add
500- 59.8= 440.2 1000- ___= ___ uL of 10mM Tris 8.5
Combine Blue and Red pools in equal parts once pools are at 1nM
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