The invention relates to a nucleic acid aptamer with the capability of binding specifically to a and inhibiting TLR-4, to a complex comprising said aptamer and a functional group, as well as to pharmaceutical compositions thereof. The invention also relates to uses and methods for detecting TLR-4 and to uses and methods for inhibiting TLR-4. Finally, the invention also relates to an aptamer for use in manufacturing a drug for the treatment of a pathology characterized by an increase in expression of TLR4 and/or an increase in activation of TLR-4.

The present invention describes methods of using Olfr90 demonstrated to bind to fungal metabolites, including a metabolite known to be detected in patients with mold (e.g. Aspergillus) infections.

The present invention describes methods of using Olfr90 demonstrated to bind to fungal metabolites, including a metabolite known to be detected in patients with mold (e.g. Aspergillus) infections.

The present invention relates to compounds, compositions, and methods are provided for covalently linking a cargo molecule, such as a therapeutic or a diagnostic agent, to a glycan in the Fab region of an antibody. Also provided are methods of modeling and producing antibodies having de novo Fab glycosylation sites. Also provided are antibody carrier conjugates, methods of using the conjugates.

The present invention relates to a method for identifying endogenous first responder protein-cysteines. Methods for screening candidate compounds suitable for regulating NF-kB signaling and the DNA damage response pathway are also disclosed.

The present invention relates to a method for identifying endogenous first responder protein-cysteines. Methods for screening candidate compounds suitable for regulating NF-kB signaling and the DNA damage response pathway are also disclosed.

Provided herein are protein-based purification matrices and methods of use thereof to purify biologics and/or to remove contaminants from a composition. Methods of bringing two or more biologics in close proximity are also provided. The disclosed compositions and methods allow for faster, more efficient purification of a biologic compared to traditional affinity chromatography.

Provided herein are protein-based purification matrices and methods of use thereof to purify biologics and/or to remove contaminants from a composition. Methods of bringing two or more biologics in close proximity are also provided. The disclosed compositions and methods allow for faster, more efficient purification of a biologic compared to traditional affinity chromatography.

Provided are methods and compositions for the heterologous expression of a payload (e.g., DNA, RNA, protein) of interest in a target cell (e.g., cancer cell). In some cases payload delivery results in expression (e.g., by a cancer cell in vivo) of a secreted immune signal such as a cytokine, a plasma membrane-tethered affinity marker (thus resulting in an induced immune response), or a cytotoxic protein such as an apoptosis inducer (e.g., by a cancer cell in vivo). Payloads are delivered with a delivery vehicle and in some cases the delivery vehicle is a nanoparticle. In some cases a subject nanoparticle includes a targeting ligand for targeted delivery to a specific cell type/tissue type (e.g., a cancerous tissue/cell). In some embodiments, payload delivery is “personalized” in the sense that the delivery vehicle and/or payload can be designed based on patient-specific information.

Provided are methods and compositions for the heterologous expression of a payload (e.g., DNA, RNA, protein) of interest in a target cell (e.g., cancer cell). In some cases payload delivery results in expression (e.g., by a cancer cell in vivo) of a secreted immune signal such as a cytokine, a plasma membrane-tethered affinity marker (thus resulting in an induced immune response), or a cytotoxic protein such as an apoptosis inducer (e.g., by a cancer cell in vivo). Payloads are delivered with a delivery vehicle and in some cases the delivery vehicle is a nanoparticle. In some cases a subject nanoparticle includes a targeting ligand for targeted delivery to a specific cell type/tissue type (e.g., a cancerous tissue/cell). In some embodiments, payload delivery is “personalized” in the sense that the delivery vehicle and/or payload can be designed based on patient-specific information.