Detection of Dengue Virus 2 with Single Infected Mosquito Resolution Using Yeast Affinity Bionanofragments and Plasmonic SERS Nanoboxes.

Dengue disease is an emerging global threat triggered by dengue virus (DENV) transmission, primarily by the mosquito Aedes aegypti. The accurate surveillance and sensitive detection of DENV in mosquito populations are critical for the protection of human populations worldwide that are in the habitat of these mosquito species. There are four DENV serotypes with DENV2 reported to cause the most severe complications. There are limited ultrasensitive methods to early detect DENV2 mosquito infection and prevent human infection. Herein, we report an innovative nanobased immunoassay platform for early, specific, and ultrasensitive detection of DENV2-secreted nonstructural 1 (NS1) protein biomarker in single infected mosquitoes with the limit of detection of 500 fg of recombinant DENV2 NS1. The high sensitivity and DENV2 serotype specificity of the platform are the result of using nanomixing, plasmonic SERS nanoboxes, and yeast affinity bionanofragments displaying single-chain variable fragments (nanoyeast scFvs). Nanoyeast scFvs used for high affinity capture of DENV2 NS1 provided an innovative and cost-efficient alternative to monoclonal antibodies and differentiated DENV2 NS1 from other DENV serotypes and Zika virus NS1. The platform used electrohydrodynamically driven nanomixing to enhance NS1 capture by the nanoyeast scFvs while reducing nonspecific interactions. High sensitivity detection of captured DENV2 NS1 was achieved using NS1-specific surface-enhanced Raman scattering (SERS) nanotags. These nanotechnologies provide a significant innovation for early DENV2 detection in single infected mosquitoes, improving the accurate surveillance of mosquito habitats and preventing infection and severe disease arising from DENV2 transmission.

Generation of Nanoyeast Single-Chain Variable Fragments as High-Avidity Biomaterials for Dengue Virus Detection.

Bioengineered yeast bio-nanomaterials termed nanoyeasts displaying antibody single-chain variable fragments (scFvs) against diagnostic targets are a promising alternative to monoclonal antibodies (mAbs). A potential limitation for translating nanoyeasts into diagnostic tools is batch-to-batch variability. Herein, we demonstrate a systematic approach for cost-efficient production of highly specific nanoyeasts that enabled accurate dengue virus (DENV) detection by immunoassay (2.5% CV). Yeasts bioengineered to surface express DENV-specific scFvs (up to 66% of the total cell population) were fragmented into nanoyeast fractions trialing sonication, bead beating, and high-pressure disruption methods. Nanoyeast fractions from sonication had optimal target binding, uniform particle size (±89 nm), were stable, and retained diagnostic activity for 7 days at 37 °C compared to traditional mAbs that lost activity after 1 day at 37 °C. We engineered a panel of nanoyeast scFvs targeting DENV nonstructural protein 1 (NS1): (i) specific for serotyping DENV 1-4 and (ii) cross-reactive anti-DENV scFvs that are suitable for "yes/no" diagnostic applications. We demonstrate highly specific nanoyeast scFvs for serotyping DENV. We show that nanoyeast scFvs specifically detect NS1 in simulated patient plasma with a limit of detection of 250 ng/mL, the concentration found in infected patients.

Expression and purification of TAT-NDRG2 recombinant protein and evaluation of its anti-proliferative effect on LNCaP cell line.

N-myc downstream regulated gene2 (NDRG2) belongs to tumor suppressor protein family of NDRG. Anti-proliferative and anti-metastasis of NDRG2 overexpression has been demonstrated in a number of tumors. The aim of this study was to fuse the gene of Trans Activator of Transcription (TAT) protein transduction domain with NDRG2 gene and express and purify TAT-NDRG2 fusion protein in order to investigate the effects of TAT-NDRG2 protein on proliferation and apoptosis of LNCaP prostate carcinoma cell line. pET28a-TAT-NDRG2 and pET28a-NDRG2 plasmids were constructed and transformed into E. coli-BL21(DE3). TAT-NDRG2 and NDRG2 proteins were expressed in the bacteria, purified using affinity chromatography and verified using western blotting. The effects of TAT-NDRG2 and NDRG2 protein treatment on LNCaP cells proliferation and apoptosis were evaluated using MTT assay and AnnexinV, 7-AAD flow cytometry assay, respectively. Western blot analysis confirmed the expression and purification of TAT-NDRG2 and NDRG2 proteins. Treatment of LNCaP cells with TAT-NDRG2 protein increased cell death and induced apoptosis significantly (P < 0.05) compared to control and NDRG2 protein-treated cells. These results suggest that TAT-NDRG2 protein can be considered as a therapeutic modality for the treatment of tumors.