2. Contents
1. Introduction
1.1. Genome organization
1.2. Common diagnostic methods for RNA viruses
2. Targets
3. Experimental section
3.1. In vitro RNA transcription
3.2. One step reverse transcription dPCR and RT-qPCR
4. Results and discussion
4.1. Specificity testing
4.2. Comparison between RT-qPCR and RT-dPCR on febrile suspected patients
4.3. Correlation between Ct value and copy number
5. Conclusions
3. COVID-19 Pandemic: One of the most serious new health threats in the modern history of humanity.
In March 2020, the WHO declared COVID-19 as pandemic,
According to the WHO & CDC, RT-qPCR: gold standard for the diagnosis of SARS-CoV-2 infection
• However, have issue of false negative rates for pharyngeal swab samples (3% of patients had negative
test results at initial while chest CT checks indicated symptoms of viral pneumonia).
Therefore, more sensitive and accurate tests are required the time.
Digital PCR (dPCR): partitions NA-molecules into a large no. of small rxns and acquires amplification
data for each partition at the endpoint based on the intensity of fluorescence.
- Offer greater precision than qPCR and is far simpler to use for copy number quantification due to the
binary nature in which the partitions are counted as positive or negative.
-More tolerant of PCR inhibition compared with qPCR due to it is an end-point PCR measurement &
less dependent on high PCR efficiency
1. Introduction
4. 1.1. Genome organization
https://viralzone.expasy.org/764
GENE EXPRESSION
-gRNA encodes ORF1a & ORF1b, it is translated by ribosomal frameshifting.
-Resulting polyproteins (pp1a & pp1ab) processed into RdRp and other non-
structural proteins (ns). Structural proteins are expressed as subgenomic RNAs.
- Monopartite, linear ssRNA(+) genome of 26-32kb in size (the largest of all RNA
virus genomes).
- family / genus Coronaviridae , Betacoronavirus
5. 1.2. Common diagnostic methods for RNA viruses
The diagnostic assays for
RNA viruses are classified
into 5 major categories:
https://aip.scitation.org/doi/10.1063/5.0021554
6. 2. Targets
To established one step RT-dPCR method for detection of open reading frame 1 ab
(ORF1ab), nucleocapsid protein (N) and envelope protein (E) gene of SARS-CoV-2.
To compared RTqPCR and RT-dPCR on 196 clinical samples and found RT-dPCR
can significantly improve the sensitivity and diagnostic accuracy of Coronavirus
disease (COVID-19)
7. 3. Experimental section
• Positive, negative and equivocal
results were all included in the
chosen specimens according to
RT-qPCR test, shown in Fig.
• RT-dPCR measurement was
conducted after RT-qPCR test.
Respiratory samples- were obtained during Feb and Mar 2020 from hospitalized patients or close contacts of hospitalized patients
tested by Beijing CDC, Wuhan CDC and a government designated clinical test laboratory.
RNA was extracted within 24 h using MagMAX-96 viral RNA isolation kit (Thermo Fisher Scientific).
8. 3.1. In vitro RNA transcription
Three in vitro transcribed RNAs were used as templates to develop RT-dPCR assays.
The genome sequence of 2019-nCoV (GenBank:NC_045512) were obtained from NCBI. Sequences containing ORF1ab (13201–15600),
E (25381-26520), and N (28261–29820) were used to order synthetic genes from BGI (Beijing, China).
9. 3.2. One step reverse transcription dPCR and RT-qPCR
Three assays for gene targets of N, ORF1ab and E of the SARS-CoV-2 were optimized on QX200 digital PCR platform.
Three different commercial RT-qPCR kits (H&R from Shanghai Huirui Biotechnology Co., Ltd, BioGerm from Shanghai BioGerm Medical Biotechnology and
Daan from Daan Gene Co., Ltd) were used for the detection.
The primer and probe sequences for detecting N and ORF1ab gene target of the SARS-CoV-2 published by the (CDC) were used for this study.
For detecting E gene target, primer and probe recommended by (WHO) was used.
Supermix 5 μL
Reverse transcriptase (RT-) 2 μL
300 mM DTT 1 μL
mixture of primers and probe 1 μL
RNA template 11 μL
Total reaction mixture 20 μL
Each reaction mix was converted to droplets using the QX200 Droplet Generator transferred to a 96-well plate, heat sealed and amplified in a GeneAmp System 9700 thermal cycler.
The thermal cycling conditions were :
-45 ℃ for 10 min (reverse transcription);
-95 ℃ for 5 min; and
-95 ℃ for 15 sec,
-58 ℃ for 30 sec; 40 cycles
-98 ℃ for 10 min.
10. 4. Results and discussion
The linear range was investigated by varying the
mean copy number per droplet, denoted as λ.
The precision/relative error of RT-dPCR : is related to
λ because RT-dPCR relies on the Poisson statistics to
account for droplets with multiple molecules.
The upper limit of N gene assay =7.8 copies/partition
To determine the lower limit of all three assays, serial
dilutions of each RNA transcript in a human total
RNA were prepared .
The measured targets matched the anticipated values
in each tested interval.
Result of E, N and ORF1ab gene copy number concentration in serial dilution of RNA transcripts spiked in 5ng/μL human total
RNA determined by gravimetrical value and RT-dPCR.
11. Evaluation of linearity of samples containing
E, ORF1ab and N gene molecules over the
extended λ range (0.0002 <λ < 7.83).
Data are shown in mean with standard
deviation for each dilution series (3 = n ≤ 10).
A good linearity (0.93<slope<1.02, R2 ≥ 0.9997) between the measured RNA target and the prepared value was observed over the range from
approximately 104 to 100 copies/reaction.
Reactions containing a mean of 60 E, 66 N or 11 ORF1ab copies fulfilled the criterion for an LoQ with a CV lower than 25%.
Validated range of the RT-dPCR assays for E, ORF1ab and N gene
12. 4.1. Specificity testing
• The Specificity of the assays for ORF1ab and E gene has been tested in a previous report.
• To further validate the specificity of all assays, Influenza virus and other human coronavirus were collected.
• All assays tests returned negative results
13. Diagnosis of SARS-CoV-2 by RT-qPCR (A,C) and RT-dPCR (B,D)
No. of
sample
RT-qPCR (%) RT-dPCR (%)
+ve -ve Equivoral +ve -ve Equivoral
103 susp 29 25 49 90 6 7
77 close
contacts
12 49 16 20 48 1
According to a follow-up survey, all the 103 patients were clinically diagnosed,
the true positive rate of SARS-CoV-2 detection was significantly improved from
28.2% to 87.4% for the 103 patients (Fig A and B).
Furthermore, the 61 samples (either negative or equivocal tested by RT-qPCR but
positive by RT-dPCR, were reported with averaged viral load of 31, 25 and 26
copies/reaction for ORF1ab, N and E, respectively.
Those 29 positive samples by RT-qPCR showed a relatively high viral load with
an average of 998, 1099 and 2594 copies/reaction for ORF1ab, N and E,
respectively.
90-29=61 samples further confirmed by RT-dPCR
4.2. Comparison between RT-qPCR & RT-dPCR on suspected patients
14. 4.3. Correlation between Ct value and copy number
(A). Correlation analysis between the Ct value of
RT-qPCR and the viral load determined by RT-
dPCR Ct value of RT-PCR was highly
correlated with the log copy number determined
by RT-dPCR (ORF1ab, R2 = 0.7078; N,
R2 = 0.7106).
(B). copy number distribution for the single gene
positive and negative specimens The viral load
was distributed in the range of 2–100 and 2–15
copy number/reaction for the specimens with the
single gene positive and negative, respectively,
detected by RT-qPCR
This very low viral load could explain why these
specimens were single gene positive or negative
reported by RT-qPCR.
15. sample collection and transportation, RNA extraction and storage, and proper performance of the kit.
(Among the RT-qPCR kits, with low sensitivity would cause high false negative rate /high equivocal rate).
• For equivocal results it is necessary to conduct a retest & would improve the positive rate of RT-qPCR.
However, it is impossible to do a same day retest due to the daily burden of thousands of incoming samples.
Therefore, availability of a highly sensitive and accurate confirmatory method is required.
Currently, other methods such as NGS and immunological detection of IgM and IgG could be used as
confirmatory methods
This would decrease the false negative rate by applying multiple methods.
Thus, digital PCR: a powerful method since significantly improve sensitivity for pharyngeal swab samples
• Furthermore, it is suitable for monitoring the change of the virus load in convalescent patients.
RT-dPCR: comparisons can be conducted b/n d/t dates and d/t laboratories as absolute quantitation of targets
by RT-dPCR provides high concordance/ ስምምነትን/ between sites, runs and operators. However, it is not
possible to compare Ct values on different runs or different machines.
• Thus, RT-dPCR is an ideal method to for measuring the change of virus load in the convalescent patients.
Factors could affect RT-PCR testing results
16. Both sensitivity and diagnostic accuracy of RT-dPCR dramatically increased to 91% and 93%, respectively.
This is very meaningful as pharyngeal swab is much easier to sampling.
Thus RT-dPCR is very sensitive for the very low viral load in suspected patients and the asymptomatic close contacts.
17. 5. Conclusions
This work demonstrates that RT-dPCR significantly improves accuracy and reduces
the false negative rate of diagnostics of SARS-CoV-2 in pharyngeal swab specimens,
which is more convenient and simpler to sampling.
Furthermore, dPCR is more sensitive and suitable for low virus load specimens from
the patients under isolation and observation who may not be exhibiting clinical
symptoms.
Finally, RT-dPCR could be used to quantitative monitoring the convalescents to
evaluate disease progression.
18.
19. 0
10
20
30
40
50
60
0.000 0.500 1.000 1.500 2.000 2.500
Frequency
Observed result of E gene copy number
(cp/reaction)
0
10
20
30
40
50
60
0.000 0.500 1.000 1.500 2.000
Frequency
Observed result of ORF1ab gene copy number
(cp/reaction)
0
10
20
30
40
50
60
0.000 1.000 2.000 3.000 4.000
Frequency
Observed result of N gene copy number
(cp/reaction)
Limit of Blank of E, ORF1ab and N gene. Recorded distributions of 60 blank measurements for
determination of limit of blank of the E (a), ORF1ab (b) and N (c) copy number per reaction.
4.1. Establishment of Limit of blank (LoB) of RT-dPCR assay
-60 blank measurements obtained from 3 blank samples were analyzed to determine the LoB.
-the distribution of the 60 blank measurements is skewed, the LoB was estimated nonparametrically
-The 15 highest blank values for each target are displayed in Table S2.
The 95th percentile corresponds to the ordered observation (=60*(0.95/60 + 0.5)). 57.5
-Linear interpolation a LoB estimate of 1.6=E, 1.6= ORF1ab, and 0.8= N copies/reaction.
20. 0
5
10
15
20
25
0.00 1.07 2.13 3.20 4.27 5.33 6.40 7.47 8.53 9.60
Frequency
Observed E CP/reaction
0
2
4
6
8
10
12
14
16
0.00 0.98 1.96 2.93 3.91 4.89 5.87 6.84 7.82 8.80
Frequency
Observed ORF1ab CP/reaction
0
2
4
6
8
10
12
14
16
18
20
0.00 1.07 2.13 3.20 4.27 5.33 6.40 7.47 8.53 9.60
Frequency
Observed N CP/reaction
Limit of detection of E, ORF1ab and N gene. Recorded distributions of 71 to 83 measurements
from 3 to 5 low concentration samples for determination of limit of detection of the E (a),
ORF1ab (b) and N (c) copy number per reaction.
determining the Limit of detection (LoD)
For determining the LoD of
1. ORF1ab gene assay: 76 measurements were performed on five samples in 3 different runs on three different days to ensure
the total assay variation is reflected. The distribution of the 76 measurement results from low concentration samples is not
Gaussian (Fig. S2A) and so that nonparametric statistics . Consequently, the LoD is determined to be 2 copies/reaction, the
lowest level material where the β-percentile is 5%.
2. N and E assay: 83 measurements of E assay on 5 samples and 71 measurements of N assay on 4 samples were performed in 4
different runs.
Similar to ORF1ab gene, the distribution of the 71 measurements for N gene and 83 measurements for E gene are not Gaussian (Fig.
S2B and S2C), and so that nonparametric statistics was used.
Consequently, the LoD is determined to be 2 copies/reaction. The data indicates LoD of the proposed RT-dPCR is 5 times and 10 times
higher than the Daan and BioGerm kit, respectively
Editor's Notes
In late December 2019, a number cases of pneumonia infection were reported in Wuhan, Hubei Province, China.
It was officially named Coronavirus disease (COVID-19) by the World Health Organization (WHO) and has since spread to 210 countries around the world
Enveloped, spherical, Monopartite, linear ssRNA(+) genome of 26-32kb in size
(the largest of all RNA virus genomes).
Capped, and polyadenylated. adding a guanosine nucleotide to the 5'-end of mRNAs and then, methylating the guanosine.
The leader RNA (65-89 bp) at the 5' end of the genome is also present at the end of each subgenomic RNAs.
Biosensors are devices used to detect the presence or concentration of a biological analyte, such as a biomolecule, a biological structure or a microorganism.
Clinical samples: were stored in viral transport medium (Yocon Biology) at 4 ◦C. Extracted RNA was stored at − 80 ◦C.
Convalescence is the gradual recovery of health and strength after illness or injury.
- Plasmids containing synthetic genes were linearized with BamHⅠ at the 3’-end of each plasmid DNA and purified as the linear template DNA.
In vitro transcription reaction was performed using MEGAscript™ T7 Transcription Kit and 1μL of TURBO DNase were added after transcription to remove the template DNA.
RNA transcripts were purified with MEGAclear™ Kit
Purity of the RNA transcripts was measured using the RNA 6000 Pico kit and analyzed on a 2100 Bioanalyzer Instrument using their 2100 Expert Software
To test the dynamic range, the purified RNA transcripts were serially diluted with RNA storage solution
RT-qPCR : standard method of diagnostics of SARS-CoV-2, plays an important role in a low positive rate
-Furthermore, it is suitable for monitoring the change of the virus load in the convalescent patients.
-RT-dPCR: comparisons can be conducted b/n d/t dates and d/t laboratories as absolute quantitation of targets by RT-dPCR provides high concordance/ ስምምነትን/ between sites, runs and operators. However, it is not possible to compare Ct values on different runs or different machines.
-Thus, RT-dPCR is an ideal method to for measuring the change of virus load in the convalescent patients.