The present invention relates to a method for the absolute quantification of naturally processed HLA-restricted cancer peptides, i.e. the determination of the copy number of peptide(s) as presented per cell. The present invention can not only be used for the development of antibody therapies or peptide vaccines, but is also highly valuable for a molecularly defined immuno-monitoring, and useful in the processes of identifying of new peptide antigens for immunotherapeutic strategies, such as respective vaccines, antibody-based therapies or adoptive T-cell transfer approaches in cancer, infectious and/or autoimmune diseases.

The present invention relates to a newly developed resorcinarene-based amphipathic compound, a method for producing the same, and a method for extracting, solubilizing, stabilizing, crystallizing, or analyzing a membrane protein by using the same. In addition, compared to a conventional compound, the compound can efficiently extract, from a cell membrane, membrane proteins having a greater variety of structures and characteristics, and can stably store such membrane proteins for a long time in an aqueous solution. Therefore, the compound can be used to analyze the functions and structures of such membrane proteins. Analysis of the structures and functions of membrane proteins, being closely related to the development of new drugs, is one of the fields of greatest interest in biology and chemistry today.

The method presented herein includes acquiring a mass spectrum of a molecule that includes mass spectrum peaks corresponding to a precursor ion and fragment ions. The method also includes identifying at least a portion of the fragment ions in the mass spectrum as corresponding to one or more monomer subunit ion of the precursor ion by appending one or more of the fragment ions to an inferable constituent to produce a topology building block. The topology building block is then stored in a candidate pool as corresponding to one or more of the monomer subunit ion if the combined mass of the inferable constituent and one or more of the fragment ions satisfy a first user-defined mass tolerance. One or more candidate topology of the precursor ion is then obtained by combining a plurality of the topology building blocks that satisfy a second user-defined mass tolerance for the precursor ion.

The present disclosure relates to a method of isolating extracellular vesicles directly from human tissues. The invention further relates to a method of identifying disease and tissue specific membrane proteins on extracellular vesicles by membrane isolation and proteomic analysis. The invention further relates to methods of diagnosing diseases by capturing extracellular vesicles by the use of disease specific membrane proteins from body fluids, and detecting or analyzing molecular signatures (proteome, DNA, and RNA) on captured extracellular vesicles. Moreover, the present invention relates to kits, apparatus and software required for implementing aforementioned methods.

The present disclosure relates to methods, compositions, systems, and kits for detecting and analyzing the glycosylation of healthy and diseased cells and protein-specific glycosylation patterns using single-cell profiling methodologies.

The present disclosure relates to methods for characterizing formulations comprising aluminum hydroxide particles (alum), an antigen bound to the alum, and an unmethylated cytidine-phospho-guanosine-containing oligodeoxynucleotide (CpG ODN). In particular, the present disclosure provides methods for determining concentration of CpG ODN in a vaccine formulation through use of a colorimetric assay for measuring total phosphorus.

Embodiments herein provide methods, apparatuses, and systems for detecting, monitoring, measuring, and/or characterizing the activity of phosphoproteins such as tyrosine kinases (TKs) and downstream proteins in TK signal transduction pathways (e.g., TK pathway proteins). In various embodiments, the methods, apparatuses, and systems may use nanoparticles, such as quantum dots (QD), to detect and/or characterize the abnormally overactive TK signaling pathways that underlie tumorgenesis and tumor progression. In various embodiments, the QD-based methods, apparatuses, and systems may have a sufficiently high degree of sensitivity to enable the identification of new TK signaling pathway markers, for example for use in diagnosing, staging, monitoring, and/or prognosing cancers, or in evaluating the efficacy of cancer therapeutics.

The present invention includes a method for analyzing reactions. The method includes the steps of providing a solution of at least one acceptor chemical and at least one donor chemical. The donor chemical is capable of donating a chemical moiety to the acceptor chemical. The solution further includes at least one controller chemical that affects the reaction between the donor chemical and the acceptor chemical. The solution is then incubated so that a portion of the acceptor chemical reacts with the donor chemical to form an acceptor product. Unreacted donor chemical is separated from the acceptor product. The acceptor product or the donor chemical is then measured using X-ray fluorescence. Another aspect of the present invention includes a method for analyzing protein function. The method includes the steps of providing a solution of at least one acceptor chemical and at least one donor chemical. The donor chemical is capable of donating a chemical moiety to the acceptor chemical. The donor chemical includes a functional group selected from ester, anhydride, imide, acyl halide, and amide. The solution is then incubated so that a portion of the acceptor chemical reacts with the donor chemical to form an acceptor product. Unreacted donor chemical is separated from the acceptor product. The acceptor product or the donor chemical is then measured using X-ray fluorescence. Yet another aspect of the present invention includes a method for analyzing protein function. The method includes the steps of providing a solution of at least one acceptor chemical and at least one donor chemical. The solution is then incubated so that a portion of the acceptor chemical reacts with the donor chemical to form an acceptor product. Unreacted donor chemical is separated from the acceptor product. The acceptor product or the donor chemical is then measured using X-ray fluorescence. An additional analytical method is also used to measure either the acceptor product or the donor chemical.

Some embodiments relate to nanoparticle probes for the detection of disease states in a patient or for tissue engineering. In some embodiments, the nanoparticle probe comprises one or more slip bonds that bind to a cell surface structure. In some embodiments, the binding of the nanoparticle probe is selective. In some embodiments, the nanoparticle probe binds to cells having a certain maximum glycocalyx thickness.

The present invention provides modified cycloalkyne compounds; and method of use of such compounds in modifying biomolecules. The present invention features a cycloaddition reaction that can be carried out under physiological conditions. In general, the invention involves reacting a modified cycloalkyne with an azide moiety on a target biomolecule, generating a covalently modified biomolecule. The selectivity of the reaction and its compatibility with aqueous environments provide for its application in vivo (e.g., on the cell surface or intracellularly) and in vitro (e.g., synthesis of peptides and other polymers, production of modified (e.g., labeled) amino acids).