Resurgence of Ebola virus in 2021 in Guinea suggests a new paradigm for outbreaks.

Seven years after the declaration of the first epidemic of Ebola virus disease in Guinea, the country faced a new outbreak-between 14 February and 19 June 2021-near the epicentre of the previous epidemic1,2. Here we use next-generation sequencing to generate complete or near-complete genomes of Zaire ebolavirus from samples obtained from 12 different patients. These genomes form a well-supported phylogenetic cluster with genomes from the previous outbreak, which indicates that the new outbreak was not the result of a new spillover event from an animal reservoir. The 2021 lineage shows considerably lower divergence than would be expected during sustained human-to-human transmission, which suggests a persistent infection with reduced replication or a period of latency. The resurgence of Zaire ebolavirus from humans five years after the end of the previous outbreak of Ebola virus disease reinforces the need for long-term medical and social care for patients who survive the disease, to reduce the risk of re-emergence and to prevent further stigmatization.

Development and Evaluation of a One-Step Quantitative RT-PCR Assay for Detection of Lassa Virus.

Lassa fever is a severe viral hemorrhagic illness caused by Lassa virus. Based on estimates, the number of LASV infections ranges from 300,000 to 500,000 cases in endemic areas with a fatality rate of 1%. Development of fast and sensitive tools for the control and prevention of Lassa virus infection as well as for clinical diagnostics of Lassa fever are crucial. Here we reported development and evaluation of a one-step quantitative RT-qPCR assay for the Lassa virus detection - LASV-Fl. This assay is suitable for the detection of lineages I-IV of Lassa virus. The limit of detection of the assay ranged from 103 copies/ml to 105 copies/ml and has 96.4% diagnostic sensitivity, whereas analytical and diagnostic specificities both were 100%. Serum, whole blood and tissue are suitable for use with the assay. The assay contains all the necessary components to perform the analysis, including an armored positive control (ARC+) and an armored internal control (IC). The study was done during the mission of specialized anti-epidemic team of the Russian Federation (SAET) in the Republic of Guinea in 2015-2018. Based on sequencing data, LASV-specific assay was developed using synthetic MS2-phage-based armored RNA particles, RNA from Lassa virus strain Josiah, and further, evaluated in field conditions using samples from patients and Mastomys natalensis rodents.

Sensitive Multiplex Real-time RT-qPCR Assay for the Detection of Filoviruses.

Filoviruses are important etiological agents of emergent diseases with high mortality rates. Traditionally, filovirus fever diseases have primarily been a burden of African countries; however, global interconnectedness has increased the probability of the worldwide spread of filoviruses. Therefore, national healthcare organizations need tools for managing filovirus risk, including diagnostic kits based on real-time reverse transcription PCR (RT-qPCR), as this is the most suitable method for diagnosing filovirus fever diseases. Here we describe a real-time RT-qPCR assay for filovirus detection. This assay is a further development of our previously reported EBOV (Zaire)-Fl kit. Two sets (FiloA-Fl and FiloB-Fl) of real-time RT-qPCR assays for the detection of filoviruses were developed and evaluated using armored RNA phage particles (ARs) as positive controls. The limit of detection of the assay was 5x102 copies/ml of the AR-positive control for the FiloA-Fl set and 5x103 copies/ml of the AR-positive control for the FiloB-Fl set. Our assay provides a rapid and sensitive tool for detecting filoviruses. The high specificity and sensitivity of the assay make it useful for clinical and epidemiologic investigations in the field of filovirus fever diseases and their etiological agents.