The present disclosure relates, in one aspect, to the discovery of a high throughput screening (HTS) method to rapidly screen for GH/GS variants that are generated using directed evolution techniques and that can significantly enhance glycosynthase catalytic activity or product specificity.

This document provides methods and materials involved in identifying and/or treating mammals having a treatment-resistant prostate cancer (e.g., an enzalutamide-resistant, castration-resistant prostate cancer). For example, methods and materials for identifying a mammal (e.g., a human) having treatment-resistant prostate cancer (e.g., an enzalutamide-resistant, castration-resistant prostate cancer) as having an elevated level of one or more polypeptides (e.g., one or more of a CXXC5, a CXXC4, a TET2, an ID1, an ID3, and/or a PFN2 polypeptide) in treatment-resistant prostate tissue are provided. Methods and materials for administering one or more targeted therapies with or without one or more chemotherapeutic agents to a mammal having treatment-resistant prostate cancer identified as having an elevated level of one or more polypeptides (e.g., one or more of a CXXC5, a CXXC4, a TET2, an ID1, an ID3, and/or a PFN2 polypeptide) in treatment-resistant prostate tissue also are provided.

The present invention relates to a pharmaceutical composition for preventing or treating neurodegenerative diseases comprising a COX2 acetylating agent as an active ingredient and, more particularly, to a pharmaceutical composition for preventing or treating neurodegenerative diseases comprising, as an active ingredient, a COX2 acetylating agent which exhibits an effect of inhibiting the deposition of amyloid- in brain neurons, reducing excessive neuroinflammatory responses, and increasing the phagocytosis of amyloid- in microglial cells. The pharmaceutical composition for preventing or treating neurodegenerative diseases comprising the COX2 acetylating agent as an active ingredient has the effects of alleviating neuroinflammation by promoting COX2 acetylation in neurons and secreting specialized pro-resolving mediators (SPMs) and thus, can be very useful in the development of a preventive or therapeutic agent for neurodegenerative diseases.

The present invention relates to a composition for diagnosis of degenerative neurological diseases and, more specifically, to a composition for diagnosis of degenerative neurological diseases, comprising an agent for measuring the level of acetylation of COX2.

According to the present invention, since acetylation of COX2 in degenerative neurological diseases is significantly reduced, whether COX2 is acetylated may be utilized as a diagnostic marker for degenerative neurological diseases, and it is possible to diagnose degenerative neurological diseases more rapidly and accurately by using same.

Cell culture compositions containing LFM-A13 or a structurally related compound can enhance global hepatic function. For example, LFM-A13 is shown to enhance levels of a broad variety of drug metabolism enzymes, including CYP enzymes, and other hepatic enzymes. LFM-A13 is also shown to promote differentiation of stem cells into hepatocytes. LFM-A13 and structurally related compounds can be used in cell culture to enhance global drug metabolism of liver cells for enhanced in vitro study the effects of drug metabolism on other candidate drug compounds.

Disclosed are methods and compositions which may be used in human cytochrome P450 (CYP450) enzyme phenotyping. The methods and compositions typically utilize substrate for CYP3A5 comprising eplerenone which may be administered orally to a subject. Subsequently, metabolites of eplereone may be detected in the subject's saliva as well as any non- metabolized eplerenone to calculate a metabolic ratio for CYP3A5 enzyme in order to generate a phenytopic CYP3A5 enzyme profile for the subject.

An automated method of evaluating a collected fluid sample includes: filling a sample cavity with the collected fluid sample; adding a buffer solution; separating the collected fluid sample into a first portion and a second portion; mixing the second portion with tagged antibodies; removing leftover tagged antibodies; and measuring a difference between the first portion and the second portion. A sample collection and testing device includes: a reference cavity comprising a reference fluid sample; a test cavity comprising a test fluid sample; a reference measurement element associated with the reference cavity; and a test measurement element associated with the test cavity. A method of evaluating a collected fluid sample including: separating the sample; pumping a first portion to a first measurement cavity; adding a solution to a second portion and pumping the mixture to a second measurement cavity; and measuring a charge difference between the first and second measurement cavities.

A method of preparing isolated microsomes comprising an irreversibly inhibited cytochrome P450 (CYP450). Isolated microsomes are characterized in that a cytochrome P450 thereof is irreversibly inhibited by a non-reversible inhibitor. The isolated microsomes according to the invention may be used in a method of phenotyping enzymatic reactions of a drug candidate.

Light-generating fusion proteins having a ligand binding site and a light-generating polypeptide moiety and their use as diagnostics, in drug screening and discovery, and as therapeutics, are disclosed. The light-generating fusion protein has a feature where the bioluminescence of the polypeptide moiety changes upon binding of a ligand at the ligand binding site. The ligand may be, for example, an enzyme present in an environment only under certain conditions, e.g., ubiquitin ligase in a hypoxic state, such that the light-generating fusion protein is turned on only under such conditions.

Provided herein are polypeptide epitopes of aspartyl-(asparaginyl)-3-hydroxylase (AABH) as well as polyepitopes thereof. Also provided are antibodies that specifically bind these polypeptide epitopes and poly epitopes, as well as binding the aspartyl-(asparaginyl)-3-hydroxylase protein itself. The disclosure further provides methods of assaying for AABH polypeptide epitopes, cells expressing these polypeptide epitopes and the AABH protein. Also provided are methods of diagnosing cancer by the detection of AABH peptides and methods of treating cancer by targeting cells that express AABH.