48 Background. Nucleic acid amplification tests (NAATs) are the primary means of 49 identifying acute infections caused by severe acute respiratory syndrome coronavirus 2 50 (SARS-CoV-2). Accurate and fast test results may permit more efficient use of protective and 51 isolation resources and allow for rapid therapeutic interventions. 52 Methods. We evaluated the analytical and clinical performance characteristics of the Xpert ® 53 Xpress SARS-CoV-2 (Xpert) test, a rapid, automated molecular test for SARS-CoV-2. 54 Analytical sensitivity and specificity/interference were assessed with infectious SARS-CoV-2, 55 other infectious coronavirus species including SARS-CoV, and 85 nasopharyngeal swab 56 specimens positive for other respiratory viruses including endemic human coronaviruses 57 (hCoVs). Clinical performance was assessed using 483 remnant upper and lower respiratory 58 specimens previously analyzed by standard of care (SOC) NAATs. 59 Results. The limit of detection of the Xpert test was 0.01 plaque forming units (PFU)/mL. 60 Other hCoVs, including Middle East Respiratory Syndrome coronavirus, were not detected by 61 the Xpert test. SARS-CoV, a closely related species in the Sarbecovirus subgenus, was 62 detected by a broad-range target (E) but was distinguished from SARS-CoV-2 (SARS-CoV-2-63 specific N2 target). Compared to SOC NAATs, the positive agreement of the Xpert test was 64 219/220 (99.5%) and the negative agreement was 250/261 (95.8%). A third tie-breaker 65 NAAT resolved all but three of the discordant results in favor the Xpert test. 66 Conclusions. The Xpert test provided sensitive and accurate detection of SARS-CoV-2 in a 67 variety of upper and lower respiratory tract specimens. The high sensitivity and fast time to 68 results of approximately 45 minutes may impact patient management. 69 70 Laboratory diagnosis of infections caused by severe acute respiratory syndrome coronavirus 2 72 (SARS-CoV-2) is usually accomplished by performing nucleic acid amplification tests 73 (NAATs) on respiratory tract specimens. An antibody response is often not detected in the 74 first week to ten days of symptoms and antibody testing is therefore generally unhelpful for 75 acute diagnosis(1-3), with virus isolation in culture presenting significant biosafety risks. 76 Upper respiratory tract (URT) specimens such as nasopharyngeal swabs (NPS) and 77 oropharyngeal swabs (OPS) generally have high SARS-CoV-2 viral loads upon symptom 78 onset.(2, 4-6) URT specimens may also have detectable RNA during the pre-symptomatic 79 period(7), and pediatric patients who remain asymptomatic through the entire course of 80 on June 9, 2020 by guest http://jcm.asm.org/ Downloaded from 4 infection can persistently shed RNA in URT specimens for two weeks or longer.(4, 8) 81 Importantly, NPS may have higher viral loads than OPS.(6) Lower respiratory tract (LRT) 82 specimens including sputum(7, 9) and tracheal aspirates(10) (TA) are often positive for RNA 83 early in disease and remain positive longer than URT sources.(5) 84 NAATs are...
Background: There is increasing concern that persistent infection of SARS-CoV-2 within immunocompromised hosts could serve as a reservoir for mutation accumulation and subsequent emergence of novel strains with the potential to evade immune responses. Methods: We describe three patients with acute lymphoblastic leukemia who were persistently positive for SARS-CoV-2 by real-time polymerase chain reaction. Viral viability from longitudinally-collected specimens was assessed. Whole-genome sequencing and serological studies were performed to measure viral evolution and evidence of immune escape. Findings: We found compelling evidence of ongoing replication and infectivity for up to 162 days from initial positive by subgenomic RNA, single-stranded RNA, and viral culture analysis. Our results reveal a broad spectrum of infectivity, host immune responses, and accumulation of mutations, some with the potential for immune escape. Interpretation: Our results highlight the potential need to reassess infection control precautions in the management and care of immunocompromised patients. Routine surveillance of mutations and evaluation of their potential impact on viral transmission and immune escape should be considered.
Many detection methods have been used or reported for the diagnosis and/or surveillance of SARS-CoV-2. Among them, reverse transcription polymerase chain reaction (RT-PCR) is the most sensitive, claiming detection of about 5 copies of viruses. However, it has been reported that only 47-59% of the positive cases were identified by RT-PCR, probably due to loss or degradation of virus RNA in the sampling process, or even mutation of the virus genome. Therefore, developing highly sensitive methods is imperative to ensure robust detection capabilities. With the goal of improving sensitivity and accommodate various application settings, we developed a multiplex-PCR-based method comprised of 172 pairs of specific primers, and demonstrated its efficiency to detect SARS-CoV-2 at low copy numbers. The assay produced clean characteristic target peaks of defined sizes, which allowed for direct identification of positives by electrophoresis. In addition, optional sequencing can provide further confirmation as well as phylogenetic information of the identified virus(es) for specific strain discrimination, which will be of paramount importance for surveillance purposes that represent a global health imperative. Finally, we also developed in parallel a multiplex-PCR-based metagenomic method that is amenable to detect SARS-CoV-2, with the additional benefit of its potential for uncovering mutational diversity and novel pathogens at low sequencing depth.
Background Full spectrum of disease phenotype and viral genotype of COVID-19 have yet to be thoroughly explored in children. Here, we analyze the relationships between viral genetic variants and clinical characteristics in children. Methods Whole genome sequencing was performed on respiratory specimens collected on all SARS-CoV-2 positive children (n=141) between March 13 to June 16, 2020. Viral genetic variations across the SARS-CoV-2 genome were identified and investigated to evaluate genomic correlates of disease severity. Results Higher viral load was detected in symptomatic patients (p=0.0007) and in children <5 years old (p=0.0004). Genomic analysis revealed a mean pairwise difference of 10.8 SNVs and the majority (55.4%) of SNVs led to an amino-acid change in the viral proteins. The D614G mutation in the spike protein was present in 99.3% of the isolates. The calculated viral mutational rate of 22.2 substitutions/year contrasts the 13.5 substitutions/year observed in California isolates without the D614G mutation. Phylogenetic clade 20C was associated with severe cases of COVID-19 (p=0.0467, OR=6.95). Epidemiological investigation revealed major representation of 3 of 5 major Nextstrain clades (20A, 20B and 20C) consistent with multiple introductions of SARS-CoV-2 in Southern California. Conclusions Genomic evaluation demonstrated greater than expected genetic diversity, presence of the D614G mutation, increased mutation rate, and evidence of multiple introductions of SARS-CoV-2 into Southern California. Our findings suggests a possible association of phylogenetic clade 20C with severe disease but small sample size precludes a definitive conclusion. Our study warrants larger and multi-institutional genomic evaluation and has implications for infection control practices.
Background There is increasing concern that persistent infection of SARS-CoV-2 within immunocompromised hosts could serve as a reservoir for mutation accumulation and subsequent emergence of novel strains with the potential to evade immune responses. Methods We describe three patients with acute lymphoblastic leukemia who were persistently positive for SARS-CoV-2 by real-time polymerase chain reaction. Viral viability from longitudinally-collected specimens was assessed. Whole-genome sequencing and serological studies were performed to measure viral evolution and evidence of immune escape. Findings We found compelling evidence of ongoing replication and infectivity for up to 162 days from initial positive by subgenomic RNA, single-stranded RNA, and viral culture analysis. Our results reveal a broad spectrum of infectivity, host immune responses, and accumulation of mutations, some with the potential for immune escape. Interpretation Our results highlight the need to reassess infection control precautions in the management and care of immunocompromised patients. Routine surveillance of mutations and evaluation of their potential impact on viral transmission and immune escape should be considered.
Genotypic and Phenotypic Diversity of Herpes Simplex Virus 2 within the Infected Neonatal Population
More than 14,000 neonates are infected with herpes simplex virus (HSV) annually. Approximately half display manifestations limited to the skin, eyes, or mouth (SEM disease). The rest develop invasive infections that spread to the central nervous system (CNS disease or encephalitis) or throughout the infected neonate (disseminated disease). Invasive HSV disease is associated with significant morbidity and mortality, but the viral and host factors that predispose neonates to these forms are unknown. To define viral diversity within the infected neonatal population, we evaluated 10 HSV-2 isolates from newborns with a range of clinical presentations. To assess viral fitness independently of host immune factors, we measured viral growth characteristics in cultured cells and found diversein vitrophenotypes. Isolates from neonates with CNS disease were associated with larger plaque size and enhanced spread, with the isolates from cerebrospinal fluid (CSF) exhibiting the most robust growth. We sequenced complete viral genomes of all 10 neonatal viruses, providing new insights into HSV-2 genomic diversity in this clinical setting. We found extensive interhost and intrahost genomic diversity throughout the viral genome, including amino acid differences in more than 90% of the viral proteome. The genes encoding glycoprotein G (gG; US4), glycoprotein I (gI; US7), and glycoprotein K (gK; UL53) and viral proteins UL8, UL20, UL24, and US2 contained variants that were found in association with CNS isolates. Many of these viral proteins are known to contribute to cell spread and neurovirulence in mouse models of CNS disease. This report represents the first application of comparative pathogen genomics to neonatal HSV disease.IMPORTANCEHerpes simplex virus (HSV) causes invasive disease in half of infected neonates, resulting in significant mortality and permanent cognitive morbidity. The factors that contribute to invasive disease are not understood. This study revealed diversity among HSV isolates from infected neonates and detected the first associations between viral genetic variations and clinical disease manifestations. We found that viruses isolated from newborns with encephalitis showed enhanced spread in culture. These viruses contained protein-coding variations not found in viruses causing noninvasive disease. Many of these variations were found in proteins known to impact neurovirulence and viral spread between cells. This work advances our understanding of HSV diversity in the neonatal population and how it may impact disease outcome.
High throughout sequencing has provided an unprecedented view of the circulating diversity of all classes of human herpesviruses. For herpes simplex virus 1 (HSV-1), we and others have previously published data demonstrating sequence diversity between hosts. However the extent of variation during transmission events, or in one host over years of chronic infection, remain unknown. Here we present an initial example of full characterization of viruses isolated from a father to son transmission event. The likely occasion of transmission occurred 17 years before the strains were isolated, enabling a first view of the degree of virus conservation after decades of recurrences, including transmission and adaptation to a new host. We have characterized the pathogenicity of these strains in a mouse ocular model of infection, and sequenced the full viral genomes. Surprisingly, we find that these two viruses have preserved their phenotype and genotype nearly perfectly during inferred transmission from father to son, and during nearly two decades of episodes of recurrent disease in each human host. Given the close genetic relationship of these two hosts, it remains to be seen whether or not this conservation of sequence will occur during non-familial transmission events.
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