ABSTRACT
Objective:To synthesize a novel site-specifically labelled probe 68Ga-1, 4, 7, 10-tetraazacyclododecane-1, 4, 7, 10-tetraacetic acid (DOTA)-Cys-Asp-Val (CDV)-Nb109 and explore its potential for detection of the programmed cell death ligand 1 (PD-L1) expression level in different tumors. Methods:Firstly, CDV was inserted into the tail of the sequence of Nb109 by genetic engineering. Then the precursor DOTA-CDV-Nb109 was prepared by mixing the maleimide-DOTA and the single-domain antibody CDV-Nb109 (amount of substance ratio 1∶1) via the maleimide-cysteine site-specific coupling strategy. Subsequently, the DOTA-CDV-Nb109 was labeled with 68Ga and purified by PD-10 column. Human melanoma A375, human PD-L1 transfected melanoma A375-hPD-L1 and human glioma U87 tumor-bearing mice models were established, and the diagnostic value of 68Ga-DOTA-CDV-Nb109 was evaluated by stability assay, cellular uptake, and microPET imaging. One-way analysis of variance and the least significant difference t test were used to analyze the data. Results:The probe 68Ga-DOTA-CDV-Nb109 was obtained with the radiochemical yield of (69.79±4.69)%, radiochemical purity more than 97%, and molar activity of (12.85±1.51) GBq/μmol. 68Ga-DOTA-CDV-Nb109 had strong binding affinity for A375-hPD-L1 with the dissociation constant ( Kd) of (66.43±17.89) nmol/L. The uptake of 68Ga-DOTA-CDV-Nb109 in A375-hPD-L1 and U87 cells were (3.17±0.15) percentage of the added radioactivity dose (%AD) and (2.08±0.03) %AD respectively, which were significantly higher than that in A375 cells ((1.21±0.14) %AD; F=82.87, t values: 15.23, 9.98, P values: <0.001, 0.003). The tumor uptake of the probe in A375-hPD-L1 ((5.21±0.35) percentage of injected dose per ml (%ID/ml)) and U87 tumor-bearing mice ((3.44±0.69) %ID/ml) were significantly higher than that in A375 tumor-bearing mice ((2.17±0.36) %ID/ml; F=249.72, t values: 35.70, 3.43, both P<0.001). Conclusion:The site-specifically labelled probe 68Ga-DOTA-CDV-Nb109, which can non-invasively and dynamically monitor the change of PD-L1 expression level in different tumors and help screen patients who can benefit from PD-L1 immune checkpoint blocking therapy, is successfully synthesized with high radiochemical purity.
ABSTRACT
RESUMEN Objetivo. Producir anticuerpos recombinantes de cadena única de alpaca que se unan con alta afinidad y especificidad al antígeno excretado-secretado (ES) de Fasciola hepatica para el desarrollo de tecnologías nuevas de diagnóstico de fascioliasis humana y animal. Materiales y métodos. Se ha construido una genoteca de cADNde los dominios variables de anticuerpos de cadena única pesada, conocidos como VHH, a partir de células mononucleares de sangre periférica de una alpaca inmunizada con el antígeno ES de F. hepatica. La genoteca fue tamizada con el antígeno ES por despliegue diferencial de fagos (phage display), seleccionando diez VHH que se unen específicamente a ES. El VHH anti ES fue clonado en un vector de expresión, la proteína recombinante (VHH-ES1) de 15,3 kDa fue producida por fermentación en E. coli y purificada a homogeneidad por cromatografía de afinidad. La unión del VHH-ES1 al antígeno ES fue evaluada por ELISA usando VHH-ES1 como anticuerpo de captura, antisuero policlonal anti-ES de conejo y conjugado anti IgG de conejo con peróxidasa de rábano. Resultados. Se ha identificado y producido un VHH-ES1 recombinante que se une al antígeno ES (VHH-ES1) que correspondía a un anticuerpo de la subclase IgG2 de bisagra larga. La unión del anticuerpo VHH-ES1 al antígeno muestra linealidad respecto a la concentración de ES en el rango de 50-5000 ng/mL y el valor límite de detección del antígeno está en el rango de 30-170 ng/mL de ES (R2=0,99). Conclusión . El VHH-ES1 se une con afinidad y especificidad al antígeno ES de F. hepatica y es un anticuerpo promisorio a evaluar para el desarrollo de nuevas tecnologías de diagnóstico de fascioliasis.
ABSTRACT Objectives. To produce recombinant single-chain antibodies from alpaca that will bind to the excreted-secreted (ES) Fasciola hepatica antigen with high affinity and specificity, so as to develop new diagnostic technologies of human and animal fascioliasis. Materials and Methods. A gene bank of DNA of the variable dominions of heavy single-chain antibodies (VHH) has been created, based on mononuclear cells of peripheral blood of an alpaca immunized with the ES antigen of F. hepatica. The gene bank was screened with the ES antigen by differential phage display, selecting ten VHH that bind specifically to ES. The anti-ES VHH was cloned in an expression vector, the recombinant protein (VHH-ES1) of 15.3 kDa was produced by fermentation in E. coli and purified to homogeneity by affinity chromatography. The binding of VHH-ES1 to the ES antigen was evaluated by ELISA using VHH-ES1 as capture antibody, policlonal anti-ES serum of rabbit and conjugated rabbit anti IgG with radish peroxidase. Results. A VHH that binds to the ES antigen (VHH-ES1) has been identified through differential phage display and produced by fermentation in E. coli; this corresponds to an antibody of the long-hinge IgG2 subclass. The binding of the VHH-ES1 antibody to the antigen shows linearity with respect to the concentration of ES in the 50-5,000 ng/mL range and the limit of detection value of the antigen is in the 30-170 ng/mL range of ES (R2=0.99). Conclusions. The VHH-ES1 binds with affinity and specificity to the ES antigen of F. hepatica and is a promissory antibody to be assessed for the development of new fascioliasis diagnostic technologies.
Subject(s)
Animals , Humans , Fasciola hepatica/immunology , Fascioliasis/diagnosis , Single-Chain Antibodies/immunology , Recombinant Proteins , Immunoglobulin G/immunology , Camelids, New World/immunology , Enzyme-Linked Immunosorbent Assay , Sensitivity and Specificity , Escherichia coli/metabolism , Fascioliasis/immunology , FermentationABSTRACT
Nanobodies,which occur naturally in Camelidae animals,are the functional heavy chain antibodies without light chains.Having the relative properties of small size,high stability,good solubility and targeting effect,nanobodies have a great potential in PET and SPECT imaging for the diagnosis and treatment of diseases,such as tumor and infectious disease.Radio-labeled nanobodies might have potential to become the molecular imaging probes of the next generation.