Your search keyword '"Julia K. Robinson"' showing total 3 results

1. Modular fluorescent nanoparticle DNA probes for detection of peptides and proteins

Author

Cassandra M. Stawicki, Torri E. Rinker, Markus Burns, Sonal S. Tonapi, Rachel P. Galimidi, Deepthi Anumala, Julia K. Robinson, Joshua S. Klein, and Parag Mallick

Subjects

Medicine, Science

Abstract

Abstract Fluorescently labeled antibody and aptamer probes are used in biological studies to characterize binding interactions, measure concentrations of analytes, and sort cells. Fluorescent nanoparticle labels offer an excellent alternative to standard fluorescent labeling strategies due to their enhanced brightness, stability and multivalency; however, challenges in functionalization and characterization have impeded their use. This work introduces a straightforward approach for preparation of fluorescent nanoparticle probes using commercially available reagents and common laboratory equipment. Fluorescent polystyrene nanoparticles, Thermo Fisher Scientific FluoSpheres, were used in these proof-of-principle studies. Particle passivation was achieved by covalent attachment of amine-PEG-azide to carboxylated particles, neutralizing the surface charge from − 43 to − 15 mV. A conjugation-annealing handle and DNA aptamer probe were attached to the azide-PEG nanoparticle surface either through reaction of pre-annealed handle and probe or through a stepwise reaction of the nanoparticles with the handle followed by aptamer annealing. Nanoparticles functionalized with DNA aptamers targeting histidine tags and VEGF protein had high affinity (EC50s ranging from 3 to 12 nM) and specificity, and were more stable than conventional labels. This protocol for preparation of nanoparticle probes relies solely on commercially available reagents and common equipment, breaking down the barriers to use nanoparticles in biological experiments.

Published

2021

2. High-density and scalable protein arrays for single-molecule proteomic studies

Author

Tural Aksel, Hongji Qian, Pengyu Hao, Pierre F. Indermuhle, Christina Inman, Shubhodeep Paul, Kevin Chen, Ryan Seghers, Julia K. Robinson, Mercedes De Garate, Brittany Nortman, Jiongyi Tan, Steven Hendricks, Subra Sankar, and Parag Mallick

Abstract

Single-molecule proteomic studies are critically important for understanding the molecular origins of cellular phenotypes. However, no currently available technology can achieve both the single-molecule sensitivity and high dynamic range required to comprehensively analyze the complex mixtures of proteins in biological samples. One approach to achieve high sensitivity across a wide dynamic range would be to create a protein array that arranges billions of single molecules with regular spacing on a patterned surface. However, creating such a protein array has remained an unsolved challenge for the field. Here, we present a highly scalable method for fabricating dense single-molecule protein arrays using a specially designed DNA origami structure, protein click-conjugation, photolithography and surface functionalization. The origami-structure is enhanced via terminal deoxynucleotidyl transferase-extension, which generates brush-like projections, increasing the effective size of the origami from 88 nm to greater than 200 nm. These particles are large enough to enable super-Poisson deposition of individual protein molecules on a nano-patterned chip (>98% occupancy with only 1% of sites occupied with multiple protein molecules). This approach allowed for single-molecule protein display of 600 million protein molecules per microscope slide-sized chip with the potential to scale further with denser feature spacing. We hypothesize that this technology will ultimately enable the development of highly scalable proteomic analysis platforms that address the currently unmet need for protein measurements at single-molecule sensitivity across an exceptionally wide dynamic range of protein concentrations.

Published

2022

3. Modular fluorescent nanoparticle DNA probes for detection of peptides and proteins

Author

Rachel P. Galimidi, Torri E. Rinker, Markus Burns, Deepthi Anumala, Joshua S. Klein, Cassandra M. Stawicki, Sonal S. Tonapi, Julia K. Robinson, and Parag Mallick

Subjects

Analyte, Science, Aptamer, Nanoparticle, Nanotechnology, Biosensing Techniques, Article, Fluorescent dyes, Polyethylene Glycols, chemistry.chemical_compound, Humans, Surface charge, Amino Acid Sequence, Sensors and probes, Multidisciplinary, Base Sequence, Staining and Labeling, Assay systems, Quantum dots, Hybridization probe, Oligonucleotide probes, Proteins, Nanobiotechnology, Aptamers, Nucleotide, Fluorescence, DNA probes, chemistry, Covalent bond, Medicine, Nanoparticles, Surface modification, Peptides, DNA

Abstract

Fluorescently labeled antibody and aptamer probes are used in biological studies to characterize binding interactions, measure concentrations of analytes, and sort cells. Fluorescent nanoparticle labels offer an excellent alternative to standard fluorescent labeling strategies due to their enhanced brightness, stability and multivalency; however, challenges in functionalization and characterization have impeded their use. This work introduces a straightforward approach for preparation of fluorescent nanoparticle probes using commercially available reagents and common laboratory equipment. Fluorescent polystyrene nanoparticles, Thermo Fisher Scientific FluoSpheres, were used in these proof-of-principle studies. Particle passivation was achieved by covalent attachment of amine-PEG-azide to carboxylated particles, neutralizing the surface charge from − 43 to − 15 mV. A conjugation-annealing handle and DNA aptamer probe were attached to the azide-PEG nanoparticle surface either through reaction of pre-annealed handle and probe or through a stepwise reaction of the nanoparticles with the handle followed by aptamer annealing. Nanoparticles functionalized with DNA aptamers targeting histidine tags and VEGF protein had high affinity (EC50s ranging from 3 to 12 nM) and specificity, and were more stable than conventional labels. This protocol for preparation of nanoparticle probes relies solely on commercially available reagents and common equipment, breaking down the barriers to use nanoparticles in biological experiments.

Published

2021