Development of High-Throughput Multiplex Serology to Detect Serum Antibodies Against

Overview

Journal Microorganisms

Specialty Microbiology

Date 2021 Nov 27

PMID 34835498

Citations 3

Authors

Rima Jeske

Larissa Dangel

Leander Sauerbrey

Dimitrios Frangoulidis

Lauren R Teras

Silke F Fischer

Tim Waterboer

Affiliations

Soon will be listed here.

Abstract

The causative agent of Q fever, the bacterium (), has gained increasing interest due to outbreak events and reports about it being a potential risk factor for the development of lymphomas. In order to conduct large-scale studies for population monitoring and to investigate possible associations more closely, accurate and cost-effective high-throughput assays are highly desired. To address this need, nine proteins were expressed as recombinant antigens for multiplex serology. This technique enables the quantitative high-throughput detection of antibodies to multiple antigens simultaneously in a single reaction. Based on a reference group of 76 seropositive and 91 seronegative sera, three antigens were able to detect infections. Com1, GroEL, and DnaK achieved specificities of 93%, 69%, and 77% and sensitivities of 64%, 72%, and 47%, respectively. Double positivity to Com1 and GroEL led to a combined specificity of 90% and a sensitivity of 71%. In a subgroup of seropositives with an increased risk for chronic Q fever, the double positivity to these markers reached a specificity of 90% and a sensitivity of 86%. Multiplex serology enables the detection of antibodies against and appears well-suited to investigate associations between infections and the clinical manifestations in large-scale studies.

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