RESUMEN
The Omicron variant of SARS-CoV-2 has rapidly replace previous variants of SARS CoV2 around the globe and is now a major variant of concern. The genomic surveillance of Omicron variant also reveals spread of its subvariant BA.2 which has differing transmissibility in comparison to its other subvariant BA.1. BA.1 and BA.2 harbors different mutational profile. One of the important change in both the subvariants is the presence of 69-70 deletion in BA.1 and absence of this deletion in BA.2. This deletion can be used as tool for the detection of omicron sub variants using real time PCR. In the current study we have used the TaqPath COVID-19 PCR kit for the detection of 69-70 deletion followed by genotyping using SNPsig(R) SARS-CoV-2 (EscapePLEX) kit (PrimerDesign, UK) that target K417N, E484K, and P681R mutations. The samples with the amplification of spike gene and K417N were termed as probable BA.2 cases. A subset of samples (n=13) were further subjected to whole genome sequencing. The results showed all the 13 samples were of BA.2. Hence, this assay can be used as a cost effective method for the detection of omicron BA.2 variant using real time PCR in resource limiting settings. Moreover, the detection of BA.2 with highly transmissible mutations in Islamabad, Pakistan may potentially increase the number of positive cases. In that scenario, there has to be stringent genomic surveillance to understand the circulating lineages in the country.
RESUMEN
The viral lineages reflecting variants of concern have emerged worldwide and among them B.1.1.7 (Alpha), B.1351 (Beta) and B.1.617.2 (Delta) variants are the most significant ones and merit close monitoring. In Pakistan, very limited information is available on the circulation of these variants and only the alpha variant has been reported as the main circulating lineage. The objective of this study was to detect and explore the genomic diversity of B.1.351 and B.1.617.2 during the third wave in the indigenous population. During the current study, a total of 2274 samples were tested on real-time PCR for the presence of SARS-CoV-2 from May 14 to May 31, 2021, and among these, 17% were spike positive, whereas 83% of samples had the spike gene target failure (SGTF). From these spike positive samples, 22 samples were processed for whole-genome sequencing. Among VOCs, 45.5% (n=10) belonged to B.1.351 followed by B.1.617.2, 36% (n=8). The delta variant cases were reported mostly from Islamabad (n = 5; 63%) followed by Peshawar and Azad Kashmir (n = 1; 13% each). Beta variant cases originated from Islamabad (n=5; 56%), Peshawar (n=2; 22%), Azad Kashmir and Rawalpindi (n=1; 11% each). The mutation profile of delta variant isolates reported significant mutations, L452R, T478K, P681R, and D950N. The beta variant isolates reported characteristic mutations, D215G, K417N, E484K, N501Y, and A701V. Notably, a characteristic mutation, E484Q was also found in delta variant, B.1.617.2. Our current findings suggest detection of these VOCs from the local population and warrants large-scale genomic surveillance in the country. In addition, it provides timely information to the health authorities to take appropriate actions.
RESUMEN
BackgroundThe ongoing COVID-19 pandemic caused by SARs-CoV-2 was transmitted person to person via droplet infections and fecal-oral transmission. This illustrates the probability of environmentally facilitated transmission, mainly the sewage. MethodWe used existing Pakistan polio environment surveillance network to investigate presence of SARs-CoV-2 using three commercially available kits and E-Gene detection published assay for surety and confirmatory of positivity. A Two-phase separation method is used for sample clarification and concentration. An additional high-speed centrifugation (14000Xg for 30 min) step was introduced, prior RNA extraction, to increase viral RNA yield resulting a decrease in Cq value. ResultsA total of 78 wastewater samples collected from 38 districts across Pakistan, 74 wastewater samples from existing polio environment surveillance sites, 3 from drains of COVID-19 infected areas and 1 from COVID 19 quarantine center drainage, were tested for presence of SARs-CoV-2. 21 wastewater samples (27%) from 13 districts turned to be positive on RT-qPCR. SARs-COV-2 RNA positive samples from areas with COVID patients and COVID 19 patient quarantine center drainage strengthen the findings and use of wastewater surveillance in future. Furthermore, sequence data of partial ORF 1a generated from COVID 19 patient quarantine center drainage sample also reinforce our findings that SARs-CoV-2 can be detected in wastewater. DiscussionThis study finding indicates that SARs-CoV-2 detection through wastewater surveillance has an epidemiologic potential that can be used as early warning system to monitor viral tracking and circulation in cities with lower COVID-19 disease burden or heavily populated areas where door-to-door tracing may not be possible. However, attention needed on virus concentration and detection assay to increase the sensitivity. Development of highly sensitive assay will be an indicator for virus monitoring and to provide early warning signs.
RESUMEN
Rationale: Severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) has been recognized as highly pathogenic. The current pandemic of SARS-CoV-2 has been spread globally and infected more than 200 countries. Patient concerns: We report the first confirmed fatal case of COVID-19 in Pakistan. A 50-year-old man returned from Saudi Arabia on March 09, 2020 and presented with cough, fever, malaise, poor appetite and difficulty in breathing to the Pulmonologist at District Headquarter Hospital Mardan. Diagnosis: The patient was initially diagnosed as COVID-19 suspected case. A oropharyngeal swab sample was positive by realtime RT-PCR tests. Lessons: This report highlights the importance of close coordination between clinicians and public health authorities as well as the importance of early laboratory-based confirmation of COVID-19 cases.