A major determinant of hnRNP C protein binding to RNA is a novel bZIP-like RNA binding domain.

The C protein tetramer of hnRNP complexes binds approximately 150-230 nt of RNA with high cooperativity (McAfee J et al., 1996, Biochemistry 35:1212-1222). Three contiguously bound tetramers fold 700-nt lengths of RNA into a 19S triangular intermediate that nucleates 40S hnRNP assembly in vitro (Huang M et al., 1994, Mol Cell Biol 14:518-533). Although it has been assumed that the consensus RNA recognition motif (RRM) of C protein (residues 8-87) is the primary determinant of RNA binding, we report here that a recombinant construct containing residues 1-115 has very low affinity for RNA at physiological ionic strength (100 mM NaCl). Moreover, we demonstrate that an N-terminal deletion construct lacking the consensus RRM but containing residues 140-290 binds RNA with an affinity sufficient to account for the total free energy change observed for the binding of intact protein. Like native C protein, the 140-290 construct is a tetramer in solution and binds RNA stoichiometrically in a salt-resistant manner in 100-300 mM NaCl. Residues 140-179 of the N-terminal truncated variant contain 11 basic and 2 acidic residues, whereas residues 180-207 specify a leucine zipper motif that directs dimer assembly. Elements within the 50-residue carboxy terminus of C protein are required for tetramer assembly. A basic region followed by a leucine zipper is identical to the domain organization of the basic-leucine zipper (bZIP) class of DNA binding proteins. Sequence homologies with other proteins containing RRMs and the bZIP motif suggest that residues 140-207 represent a conserved bZIP-like RNA binding motif (designated bZLM). The steric orientation of four high-affinity RNA binding sites about rigid leucine zipper domains may explain in part C protein''s asymmetry, its large occluded site size, and its RNA folding activity.     

Structure-based design of a leucine zipper protein with new DNA contacting region

We have employed a structure-based design to construct a small folding domain from the F-actin bundling protein villin that contains the amino acids necessary for the DNA binding of the basic leucine zipper protein GCN4 and have compared its DNA binding with GCN4. The monomeric motif folds into a stable domain and binds DNA in a rigid-body mechanism, while its affinity is not higher than that of the basic region peptide. The addition of the leucine zipper region to the folded domain restored its sequence-specific DNA binding comparable to that of GCN4. Unlike the monomeric folded domain, its leucine zipper derivative undergoes a conformational change upon DNA binding. CD spectral and thermodynamic studies indicate that the DNA-contacting region is folded in the presence or absence of DNA and suggest that the junction between the DNA-contacting and the leucine zipper regions transits to a helix in the presence of DNA. These results demonstrate that the structural transition outside the direct-contacting region, which adjusts the precise location of the DNA-contacting region, plays a critical role in the specific complex formation of basic leucine zipper proteins.     

Dual DNA recognition codes of a short peptide derived from the basic leucine zipper protein EmBP1

Sequence-specific DNA binding of short peptide dimers derived from a plant basic leucine zipper protein EmBP1 was studied. A homodimer of the EmBP1 basic region peptide recognized a palindromic DNA sequence, and a heterodimer of EmBP1 and GCN4 basic region peptides targets a non-palindromic DNA sequence when a beta-cyclodextrin/adamantane complex is utilized as a dimerization domain. A homodimer of the EmBP1 basic region peptide binds the native EmBP1 binding 5'-GCCACGTGGC-3' and the native GCN4 binding 5'-ATGACGTCAT-3' sequences with almost equal affinity in the alpha-helical conformation, indicating that the basic region of EmBP1 by itself has a dual recognition codes for the DNA sequences. The GCN4 basic region peptide binds 5'-ATGAC-3' in the alpha-helical conformation, but it neither shows affinity nor helix formation with 5'-GCCAC-3'. Because native EmBP1 forms 100 times more stable complex with 5'-GCCACGTGGC-3' over 5'-ATGACGTCAT-3', our results suggest that the sequence-selectivity of native EmBP1 is dictated by the structure of leucine zipper dimerization domain including the hinge region spanning between the basic region and the leucine zipper.