Disclosed herein are methods for identifying a ubiquitin ligase agonist, and the methods include (a) contacting a ubiquitin ligase with a candidate agonist and a neo-substrate; and (b) determining whether the candidate agonist is effective to result in binding the ubiquitin ligase to the neo-substrate, wherein binding of the ubiquitin substrate to the neo-substrate identifies the candidate agonist as a ubiquitin ligase agonist.

Disclosed herein are methods for identifying a ubiquitin ligase agonist, and the methods include (a) contacting a ubiquitin ligase with a candidate agonist and a neo-substrate; and (b) determining whether the candidate agonist is effective to result in binding the ubiquitin ligase to the neo-substrate, wherein binding of the ubiquitin substrate to the neo-substrate identifies the candidate agonist as a ubiquitin ligase agonist.

The disclosure generally provides compositions and methods that are useful in the treatment of cancer. More specifically, the methods and compositions may be used to detect, quantify, inhibit, kill, differentiate, or eliminate cancer stem cells (CSCs) and may be used in the treatment of cancers associated with CSCs, and particularly cancers and CSCs that express LOX1.

The disclosure generally provides compositions and methods that are useful in the treatment of cancer. More specifically, the methods and compositions may be used to detect, quantify, inhibit, kill, differentiate, or eliminate cancer stem cells (CSCs) and may be used in the treatment of cancers associated with CSCs, and particularly cancers and CSCs that express LOX1.

The disclosure generally provides compositions and methods that are useful in the treatment of cancer. More specifically, the methods and compositions may be used to detect, quantify, inhibit, kill, differentiate, or eliminate cancer stem cells (CSCs) and may be used in the treatment of cancers associated with CSCs, and particularly cancers and CSCs that express LOX1.

The disclosure generally provides compositions and methods that are useful in the treatment of cancer. More specifically, the methods and compositions may be used to detect, quantify, inhibit, kill, differentiate, or eliminate cancer stem cells (CSCs) and may be used in the treatment of cancers associated with CSCs, and particularly cancers and CSCs that express LOX1.

An activity-based nanosensor composition for detecting protease activity comprising a cleavable detectable substrate and methods of use are disclosed.

The present invention belongs to the field of plant genetic engineering. Specifically, the invention relates to a method for creating novel herbicide resistant plants by base editing techniques and a method for screening endogenous gene mutation sites capable of conferring herbicide resistance in plants. The invention also relates to the use of the identified endogenous gene mutantation sites in crop breeding.

Aspects of the present disclosure include methods that include co-culturing a cell and a microparticle that includes a capture ligand, in a culture medium under conditions in which a biomarker produced by the cell is bound by the capture ligand. Such methods may further include detecting (e.g., by flow or mass cytometry) complexes that include the microparticle, the capture ligand, the biomarker, and a detection reagent. The methods may further include determining the proportion or number of cells among a heterogeneous cell population that produced the biomarker and/or the level of biomarker secreted by such cells. Compositions, systems and kits are also provided.

The invention includes, in part, methods and compounds for diagnosing diseases and conditions characterized by altered threonyl-tRNA synthetase (TARS) activity, which include, but are not limited to diseases and conditions in which angiogenesis is altered. In some embodiments of the invention, a level of a TARS molecule is determined and compared to a control level of TARS to assess onset, progression, and/or regression of a disease or condition associated with altered TARS activity.