Abstract: One or more techniques and/or systems are disclosed for leveling a rotary cutter that includes a center cutting portion, a first cutting wing pivotally coupled to the center cutting portion, a second cutting wing pivotally coupled to the center cutting portion, and an actuator system having a center leveling sub-system, a first wing leveling sub-system, and a second wing leveling sub-system. The actuator system is configured to synchronously adjust the height of the center cutting portion, the first cutting wing, and the second cutting wing. The first wing leveling sub-system is configured to adjust the height of the first cutting wing independent from the center cutting portion and the second cutting wing, and the second wing leveling sub-system is configured to adjust the height of the second cutting wing independent from the center cutting portion and the first cutting wing.

Abstract: Chemically induced dimerizers (AbCIDs) have emerged as one of the most powerful tools to artificially regulate signaling pathways in cells; however, no facile method to identify or design these systems currently exists. The present invention provides a methodology to rapidly generate antibody-based chemically induced dimerizers (AbCIDs) from known small-molecule-protein complexes by selecting for synthetic antibodies that recognize the chemical epitope created by the bound small molecule. Success of this strategy is demonstrated by generating ten chemically-inducible antibodies against the BCL-xL/ABT-737 complex. Three of the antibodies are highly selective for the BCL-xL/ABT-737 complex over BCL-xL alone. Two exemplary important cellular applications of AbCIDs are demonstrated by applying them intracellularly to induce CRISPRa-mediated gene expression and extracellularly to regulate CAR T-cell activation with the small molecule, ABT-737.

Abstract: The present invention uses an indinavir based mechanism of “chemically induced dimerization” to enable a precise temporal control of the activity of a T cell engaging complex in a patient.

Abstract: Chemically induced dimerizers (AbCIDs) have emerged as one of the most powerful tools to artificially regulate signaling pathways in cells; however, no facile method to identify or design these systems currently exists. The present invention provides a methodology to rapidly generate antibody-based chemically induced dimerizers (AbCIDs) from known small-molecule-protein complexes by selecting for synthetic antibodies that recognize the chemical epitope created by the bound small molecule. Success of this strategy is demonstrated by generating ten chemically-inducible antibodies against the BCL-xL/ABT-737 complex. Three of the antibodies are highly selective for the BCL-xL/ABT-737 complex over BCL-xL alone. Two exemplary important cellular applications of AbCIDs are demonstrated by applying them intracellularly to induce CRISPRa-mediated gene expression and extracellularly to regulate CAR T-cell activation with the small molecule, ABT-737.

Abstract: The present disclosure provides a system that enables precise temporal control of the serum half-life a therapeutic moiety by inducing the association or disassociation of the therapeutic moiety with an Fc domain by a small molecule. The present disclosure also provides a system that enables precise control of the serum half- life a T cell engager domain by incorporating a chemically induced dimerizer (CID). One half of the CID is fused to a T cell engager, and the other half of the CID is fused to a HSA binding domain. Addition or removal of a small molecule induces association or dissociation of the T cell engager with HSA, thereby enabling precise temporal control of the serum half-life the T cell engager.

Abstract: The present invention provides antibody-based chemically induced dimerizers (AbCIDs) comprising an antibody domain that recognizes a chemical epitope created by the binding of an IMiD to a binding partner, such as cereblon, and methods to rapidly generate such AbCIDs. Several aspects described herein relate to systems, compositions, and methods including components of a chemically induced dimerizer (CID), such as an antibody chemically induced dimerizer (AbCID).

Abstract: Chemically induced dimerizers (AbCIDs) have emerged as one of the most powerful tools to artificially regulate signaling pathways in cells; however, no facile method to identify or design these systems currently exists. The present invention provides a methodology to rapidly generate antibody-based chemically induced dimerizers (AbCIDs) from known small-molecule-protein complexes by selecting for synthetic antibodies that recognize the chemical epitope created by the bound small molecule. Success of this strategy is demonstrated by generating ten chemically-inducible antibodies against the BCL-xL/ABT-737 complex. Three of the antibodies are highly selective for the BCL-xL/ABT-737 complex over BCL-xL alone. Two exemplary important cellular applications of AbCIDs are demonstrated by applying them intracellularly to induce CRISPRa-mediated gene expression and extracellularly to regulate CAR T-cell activation with the small molecule, ABT-737.