Abstract: A programmable modular protein architecture for RNA binding comprises a set of modules, derived from RNA-binding protein Pumilio, that can be concatenated into chains of varying composition and length. When bound into a chain, each module has a preferred affinity for a specific RNA base. The chains can bind arbitrary RNA sequences with high specificity and fidelity by varying the sequence of modules within the chains. Each module contains at least 6 amino acids, with the amino acids in positions 1 and 5 providing the preferred affinity for the specific base, and the amino acid at position 2 serving as a stacking unit between concatenated modules. The modules may have four canonic forms, each having a preferred affinity for a different base and characterized by the base with which it has affinity, the two amino acids that provide the affinity, and the amino acid that serves as a stacking unit.

Abstract: A programmable modular protein architecture for RNA binding comprises a set of modules, derived from RNA-binding protein Pumilio, that can be concatenated into chains of varying composition and length. When bound into a chain, each module has a preferred affinity for a specific RNA base. The chains can bind arbitrary RNA sequences with high specificity and fidelity by varying the sequence of modules within the chains. Each module contains at least 6 amino acids, with the amino acids in positions 1 and 5 providing the preferred affinity for the specific base, and the amino acid at position 2 serving as a stacking unit between concatenated modules. The modules may have four canonic forms, each having a preferred affinity for a different base and characterized by the base with which it has affinity, the two amino acids that provide the affinity, and the amino acid that serves as a stacking unit.

Abstract: A programmable modular protein architecture for RNA binding comprises a set of modules, derived from RNA-binding protein Pumilio, that can be concatenated into chains of varying composition and length. When bound into a chain, each module has a preferred affinity for a specific RNA base. The chains can bind arbitrary RNA sequences with high specificity and fidelity by varying the sequence of modules within the chains. Each module contains at least 6 amino acids, with the amino acids in positions 1 and 5 providing the preferred affinity for the specific base, and the amino acid at position 2 serving as a stacking unit between concatenated modules. The modules may have four canonic forms, each having a preferred affinity for a different base and characterized by the base with which it has affinity, the two amino acids that provide the affinity, and the amino acid that serves as a stacking unit.

Abstract: A programmable modular protein architecture for RNA binding comprises a set of modules, derived from RNA-binding protein Pumilio, that can be concatenated into chains of varying composition and length. When bound into a chain, each module has a preferred affinity for a specific RNA base. The chains can bind arbitrary RNA sequences with high specificity and fidelity by varying the sequence of modules within the chains. Each module contains at least 6 amino acids, with the amino acids in positions 1 and 5 providing the preferred affinity for the specific base, and the amino acid at position 2 serving as a stacking unit between concatenated modules. The modules may have four canonic forms, each having a preferred affinity for a different base and characterized by the base with which it has affinity, the two amino acids that provide the affinity, and the amino acid that serves as a stacking unit.

Abstract: A programmable modular protein architecture for RNA binding comprises a set of modules, derived from RNA-binding protein Pumilio, that can be concatenated into chains of varying composition and length. When bound into a chain, each module has a preferred affinity for a specific RNA base. The chains can bind arbitrary RNA sequences with high specificity and fidelity by varying the sequence of modules within the chains. Each module contains at least 6 amino acids, with the amino acids in positions 1 and 5 providing the preferred affinity for the specific base, and the amino acid at position 2 serving as a stacking unit between concatenated modules. The modules may have four canonic forms, each having a preferred affinity for a different base and characterized by the base with which it has affinity, the two amino acids that provide the affinity, and the amino acid that serves as a stacking unit.

Abstract: A programmable modular protein architecture for RNA binding comprises a set of modules, derived from RNA-binding protein Pumilio, that can be concatenated into chains of varying composition and length. When bound into a chain, each module has a preferred affinity for a specific RNA base. The chains can bind arbitrary RNA sequences with high specificity and fidelity by varying the sequence of modules within the chains. Each module contains at least 6 amino acids, with the amino acids in positions 1 and 5 providing the preferred affinity for the specific base, and the amino acid at position 2 serving as a stacking unit between concatenated modules. The modules may have four canonic forms, each having a preferred affinity for a different base and characterized by the base with which it has affinity, the two amino acids that provide the affinity, and the amino acid that serves as a stacking unit.