Provided are methods and compositions for enhancing treatment of a cancer by administering a therapeutic agent for the treatment of a cancer together with a second agent that elevates the level of protein p53. The second agent generates in the tumor a population of dendritic cells expressing at least one of Batf3, IRF5, CD103, and XCR1. The second therapeutic agent can also suppress an autoimmune response to non-cancerous tissue in the patient if generated by an immunotherapeutic agent. The method can further comprise administering a PTEN phosphatase inhibitor.

The present invention provides a mannose-based mRNA targeted delivery system and use thereof. The mRNA can encode one or more target polypeptides and contains at least one mannose modification. The technical solution of the present invention modifies the mRNA molecule with a mannose, so that the mRNA can be directly and efficiently coupled with the mannose, and the targeted delivery of the mRNA is realized without the need for a carrier.

The present invention provides a mannose-based mRNA targeted delivery system and use thereof. The mRNA can encode one or more target polypeptides and contains at least one mannose modification. The technical solution of the present invention modifies the mRNA molecule with a mannose, so that the mRNA can be directly and efficiently coupled with the mannose, and the targeted delivery of the mRNA is realized without the need for a carrier.

Compositions and methods for the prevention and/or treatment of SARS-CoV-2 infection and/or COVID-19 are described.

Immunogen enhancers for admixture with an antigen of interest are described herein. The enhancers generally comprise a steroid acid and/or a steroid acid-peptide conjugate in an amount sufficient to improve or modify the adaptive immune response to antigens admixed therewith. In embodiments, the steroid acid may be a bile acid and the peptide may comprise one or more functional domains, such as a nuclear localization signal, which may facilitate antigen-presentation and/or antigen cross-presentation, thereby triggering improved cellular immunity, or improved cellular and humoral immunity, against the antigen.

Immunogen enhancers for admixture with an antigen of interest are described herein. The enhancers generally comprise a steroid acid and/or a steroid acid-peptide conjugate in an amount sufficient to improve or modify the adaptive immune response to antigens admixed therewith. In embodiments, the steroid acid may be a bile acid and the peptide may comprise one or more functional domains, such as a nuclear localization signal, which may facilitate antigen-presentation and/or antigen cross-presentation, thereby triggering improved cellular immunity, or improved cellular and humoral immunity, against the antigen.

The present invention provides soluble single wall nanotube (SWNT) constructs functionalized with a plurality of a targeting moiety and a plurality of one or more payload molecules attached thereto. The targeting moiety and the payload molecules may be attached to the soluble SWNT via a DNA or other oligomer platform attached to the SWNT. These soluble SWNT constructs may comprise a radionuclide or contrast agent and as such are effective as diagnostic and therapeutic agents. Methods provided herein are to diagnosing or locating a cancer, treating a cancer, eliciting an immune response against a cancer or delivering an anticancer drug in situ via an enzymatic nanofactory using the soluble SWNT constructs.

The present invention provides soluble single wall nanotube (SWNT) constructs functionalized with a plurality of a targeting moiety and a plurality of one or more payload molecules attached thereto. The targeting moiety and the payload molecules may be attached to the soluble SWNT via a DNA or other oligomer platform attached to the SWNT. These soluble SWNT constructs may comprise a radionuclide or contrast agent and as such are effective as diagnostic and therapeutic agents. Methods provided herein are to diagnosing or locating a cancer, treating a cancer, eliciting an immune response against a cancer or delivering an anticancer drug in situ via an enzymatic nanofactory using the soluble SWNT constructs.

Disclosed is synthesis of an O-Antigen oligosaccharide compound of Helicobacter pylori serotype O2, belonging to the field of organic synthesis. The disclosure obtains O-antigen disaccharide to tetracosasaccharide of Helicobacter pylori serotype O.sub.2 by chemical synthesis. A chemical synthesis method which is quite conducive to production of a glucose-α-lglucosidic bond is developed in the disclosure by a protectant strategy, temperature effect, solvent effect, and additive effect. The method is applied in synthesis of an O-antigen oligosaccharide compound of Helicobacter pylori serotype O2 assembled with an amino linking arm. A saccharide conjugate can be prepared from the synthesized O-antigen oligosaccharide compound of Helicobacter pylori serotype O2 assembled with an amino linking arm together with a carrier protein for immunology researches, playing an important role in preventing and treating Helicobacter pylori.

Meningococcal vaccines can be improved by including multiple alleles or variants of fHbp, in order to provide broader coverage of the diversity which is known for this protein, and/or by reducing the quantity of an OMV component in each dose.