The aryl hydrocarbon receptor mediates sex ratio distortion in the embryos sired by TCDD-exposed male mice.

Many reports describe an association between preconceptional paternal exposure to environmental chemicals, including the persistent organic pollutant 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) with an increased number of female offspring. We chronically treated wild-type C57BL/6 male mice with TCDD to investigate a role for the aryl hydrocarbon receptor (AHR) transcription factor. These mice had a 14 % lower male:female sex ratio than control mice, which was not observed in TCDD-treated Ahr knock out mice.

Molecular Imaging of Mesothelin-Expressing Ovarian Cancer with a Human and Mouse Cross-Reactive Nanobody.

Mesothelin is an epithelial marker highly expressed at the cell surface of cancer cells from diverse origins, including ovarian and pancreatic adenocarcinomas and mesotheliomas. Previously, we identified and characterized an antimesothelin nanobody (NbG3a) for in vitro diagnostic applications. The main goal of this research was to establish the potential of NbG3a as a molecular imaging agent.

High-throughput sexing of mouse blastocysts by real-time PCR using dissociation curves.

Sex ratio is defined as the proportion of males to females in a population. Subdivisions of the sex ratio are the primary (ratio at fertilization) and the secondary (ratio at birth). The expected secondary sex ratio is 0.

Anti-Mesothelin Nanobodies for Both Conventional and Nanoparticle-Based Biomedical Applications.

Mesothelin, a cancer biomarker overexpressed in tumors of epithelial origin, is a target for nanotechnology-based diagnostic, therapeutic, and prognostic applications. The currently available anti-mesothelin antibodies present limitations, including low penetration due to large size and/or lack of in vivo stability. Single domain antibodies (sdAbs) or nanobodies (Nbs) provide powerful solutions to these specific problems.

Biological barriers and current strategies for modifying nanoparticle bioavailability.

Nanoparticles are diligently crafted with exacting control over size, shape, and composition. The pristine nanoparticles are rigorously characterized in vitro by numerous physical and materials science techniques. Immediately after being exposed to body fluids, nanoparticles interact with a heterogeneous mixture of proteins and numerous different cell types that modify the nanoparticle surface and affect their bioavailability.

Facile immunotargeting of nanoparticles against tumor antigens using site-specific biotinylated antibody fragments.

Nanotechnology is actively being developed for preclinical and clinical oncology applications. Nanoparticle-based immunotargeting against tumor antigens with antibodies or antibody fragments is designed to increase the nanoparticle concentration at the tumor site. However, chemical-based strategies for bioconjugating antibody fragments to nanoparticles typically result in a functionally heterogeneous population of conjugates due to alteration of amino acids within the antigen binding site.

Designing tripodal and triangular gadolinium oxide nanoplates and self-assembled nanofibrils as potential multimodal bioimaging probes.

Here, we report the shape-controlled synthesis of tripodal and triangular gadolinium oxide (Gd2O3) nanoplates. In the presence of lithium ions, the shape of the nanocrystals is readily controlled by tailoring reaction parameters such as temperature and time. We observe that the morphology transforms from an initial tripodal shape to a triangular shape with increasing reaction time or elevated temperatures.

Magnetization transfer induced biexponential longitudinal relaxation.

Longitudinal relaxation of brain water (1)H magnetization in mammalian brain in vivo is typically analyzed on a per-voxel basis using a monoexponential model, thereby assigning a single relaxation time constant to all (1)H magnetization within a given voxel. This approach was tested by obtaining inversion recovery (IR) data from gray matter of rats at 64 exponentially spaced recovery times. Using Bayesian probability for model selection, brain water data were best represented by a biexponential function characterized by fast and slow relaxation components.

Permeation peptide conjugates for in vivo molecular imaging applications.

Rapid and efficient delivery of imaging probes to the cell interior using permeation peptides has enabled novel applications in molecular imaging. Membrane permeant peptides based on the HIV-1 Tat basic domain sequence, GRKKRRQRRR, labeled with fluorophores and fluorescent proteins for optical imaging or with appropriate peptide-based motifs or macrocycles to chelate metals, such as technetium for nuclear scintigraphy and gadolinium for magnetic resonance imaging, have been synthesized. In addition, iron oxide complexes have been functionalized with the Tat basic domain peptides for magnetic resonance imaging applications.

Synthesis and characterization of a Gd-DOTA-D-permeation peptide for magnetic resonance relaxation enhancement of intracellular targets.

Many MR contrast agents have been developed and proven effective for extracellular nontargeted applications, but exploitation of intracellular MR contrast agents has been elusive due to the permeability barrier of the plasma membrane. Peptide transduction domains can circumvent this permeability barrier and deliver cargo molecules to the cell interior. Based upon enhanced cellular uptake of permeation peptides with D-amino acid residues, an all-D Tat basic domain peptide was conjugated to DOTA and chelated to gadolinium.

Selectivity in heavy metal- binding to peptides and proteins.

The metal-binding affinities and three-dimensional structures of three synthetic 18-residue peptides with sequences derived from that of the highly conserved metal-binding motif MXCXXC found in many heavy metal-binding proteins were determined. A change in register of the cysteines and alanines of the sequence from the periplasmic mercury-binding protein, MerP, i.e.