Evaluation of rapid blood sample collection in the detection of circulating filarial antigens for epidemiological survey by rWbSXP-1 capture assay

Recombinant antigens used as diagnostic tools for lymphatic filariasis

Lymphatic filariasis (LF) is a parasitic disease caused by the worms Wuchereria bancrofti, Brugia malayi, or Brugia timori. It is a tropical and subtropical illness that affects approximately 67 million people worldwide and that still requires better diagnostic tools to prevent its spread and enhance the effectiveness of control procedures. Traditional parasitological tests and diagnostic methods based on whole protein extracts from different worms are known for problems related to sample time collection, sensitivity, and specificity. More recently, new diagnostic tools based on immunological methods using recombinant antigens have been developed. The current review describes the several recombinant antigens used as tools for lymphatic filariasis diagnosis in antigen and antibody capture assays, highlighting their advantages and limitations as well as the main commercial tests developed based on them. The literature chronology is from 1991 to 2021. First, it describes the historical background related to the identification of relevant antigens and the generation of the recombinant polypeptides used for the LF diagnosis, also detailing features specific to each antigen. The subsequent section then discusses the use of those proteins to develop antigen and antibody capture tests to detect LF. So far, studies focusing on antibody capture assays are based on 13 different antigens with at least six commercially available tests, with five proteins further used for the development of antigen capture tests. Five antigens explored in this paper belong to the SXP/RAL-2 family (BmSXP, Bm14, WbSXP-1, Wb14, WbL), and the others are BmShp-1, Bm33, BmR1, BmVAH, WbVAH, BmALT-1, BmALT-2, and Wb123. It is expected that advances in research with these antigens will allow further development of tests combining both sensitivity and specificity with low costs, assisting the Global Program to Eliminate Lymphatic Filariasis (GPELF).

Molecular evolution of single chain fragment variable (scFv) for diagnosis of lymphatic filariasis

Endemic countries with lymphatic filariasis are striving towards the Global Program to Eliminate Lymphatic Filariasis (GPELF) by 2020. Efficient and cost-effective diagnostic tools to assess active filarial infection are critical to eradicate lymphatic filariasis. Detection of circulating filarial antigens in sera is one of the precise methods to identify this infection. Monoclonal antibodies and single chain fragment variable (scFv) against Wuchereria bancrofti antigen SXP1 have been developed for antigen detection. Molecular cloning of scFv for recombinant expression has laid a platform for developing novel genetic constructs with enhanced reactivity. In this study, a simple procedure is developed to create diverse libraries of scFv based on a single DNA framework with all the requisites for an in vitro protein synthesis and ribosomal display. Error Prone-PCR was performed to incorporate random mutations and screened by ribosome display technique to isolate evolved scFv. Evolved scFv with six mutations showed tenfold increase in affinity compared to wild-type scFv for rWbSXP1. In silico studies showed that four mutations introduced unique molecular interactions between the evolved scFv and SXP1. Reactivity with asserted clinical samples of endemic normals (EN), microfilariaemic (MF), chronic pathology (CP) and non-endemic normals (NEN) showed significant augment (59.69%, p < 0.0001) in reactivity to MF samples with evolved scFv in comparison to wild-type scFv. Sensitivity of scFv was increased from 15.62 ng to 195 pg by evolved scFv in serum samples. This evolutionary method coupled with ribosome display has facilitated us to improve the reactivity of the ScFv without diminishing the specificity.