Regulation of gene expression by many transcription factors is controlled by specific combinations of homo-and heterodimers through a short ␣-helical coiled-coil known as a leucine zipper. The dimer interface of a leucine zipper involves side chains of the residues at the a, d, e, and g positions of the (abcdefg) n heptad repeat. To understand the basis for the specificity of dimer formation, we characterized GCN4 leucine zipper mutants with all 16 possible permutations and combinations of isoleucines and asparagines at four a positions in the dimer interface, using a genetic test for the specificity of dimer formation by repressor-leucine zipper fusions. Heterodimers were detected by loss of repressor activity in the presence of a fusion to a dominant-negative mutant form of the DNA-binding domain of repressor. Reconstruction experiments using leucine zippers from GCN4, Jun, Fos, and C͞EBP showed that this assay distinguishes pairs that form heterodimers from those that do not. We found that the mutants have novel dimerization specificities determined by the positioning of buried asparagine residues at the a positions. The pattern of buried polar residues could also explain the dimerization specificities of some naturally occurring leucine zippers. The altered specificity mutants described here should be useful for the construction of artificial regulatory circuitry.The stoichiometry and specificity with which proteins interact is a key control point in many biological processes. For example, common dimerization domains allow transcription factors in the bZIP or bHLH-LZ families to form a variety of homo-and heterodimers with different properties. By expressing different sets of subunits under different conditions, cells can generate complex regulatory circuits from a relatively small number of genes. The correct functioning of this complex regulatory machinery depends on each of the component proteins assembling only with specific partners.Leucine zippers are an excellent model system to study how the stability and specificity of protein-protein interactions are determined. High-resolution x-ray crystallographic and NMR structures are available for several leucine zippers (1-7). As ␣-helical coiled coils, leucine zippers have simple secondary and tertiary structures. Moreover, the large number of naturally occurring leucine zipper proteins includes a wide variety of distinct and overlapping dimerization specificities. At the amino acid sequence level, leucine zippers are characterized by leucine appearing in every seventh position (d) over 4 to 5 heptad repeats (abcdefg) n . The hydrophobic core of the dimer interface is formed by residues at the a and d positions (Fig. 1); the solvent-accessible e and g positions are frequently occupied by charged amino acids (8, 9). In the crystal structures of leucine zippers, including GCN4 homodimers and Jun-Fos heterodimers, intersubunit salt bridges are seen between oppositely charged amino acids at the g (ith heptad) and eЈ (i ϩ 1th heptad of the other monomer)...
Putative intersubunit electrostatic interactions between charged amino acids on the surfaces of the dimer interfaces of leucine zippers (g-e' ion pairs) have been implicated as determinants of dimerization specificity. To evaluate the importance of these ionic interactions in determining the specificity of dimer formation, we constructed a pool of >65,000 GCN4 leucine zipper mutants in which all the e and g positions are occupied by different combinations of alanine, glutamic acid, lysine, or threonine. The oligomerization properties of these mutants were evaluated based on the phenotypes of cells expressing A repressor-leucine zipper fusion proteins. About 90% of the mutants do not form stable homooligomers. Surprisingly, approximately 8% of the mutant sequences have phenotypes consistent with the formation of higher-order (>dimer) oligomers, which can be classified into three types based on sequence features. The oligomerization states of mutants from two of these types were determined by characterizing purified fusion proteins. The Type I mutant behaved as a tetramer under all tested conditions, whereas the Type I11 mutant formed a variety of higher-order oligomers, depending on the solution conditions. Stable homodimers comprise less than 3% of the pool; several g-e' positions in these mutants could form attractive ion pairs. Putative repulsive ion pairs are not found among the homodimeric mutants. However, patterns of charged residues at the e and g positions do not seem to be sufficient to predict either homodimer or heterodimer formation among the mutants.Keywords: dimerization specificity; leucine zippers; protein structure; recombinant fusion proteins; site-directed mutagenesis a-Helical coiled coils are involved in the assembly of a wide variety of proteins. A subclass of the coiled-coils known as leucine zippers are found as short dimerization motifs in many eukaryotic transcription factors. Leucine zipper sequences are characterized by leucine appearing in every seventh position (4 over four to five heptad repeats (abcdefg), (for a review, see Hurst, 1994). Leucine zippers fold into dimeric, parallel coiled-coils, where each heptad forms two a-helical turns. Because of their small size and simple structure, leucine zippers and other short a-helical coiled coils have been used extensively as a model system to study how amino acid sequences specify structure (e.g., see Hodges et al., 1988;
Changes in unfolding and enzymatic activity of bovine carbonic anhydrase II (BCA II) in different concentrations of 2,2,2-trifluoroethanol (TFE) were investigated by 1-anilino-8-naphthalenesulfonate (ANS) fluorescence emission spectra, far-UV CD spectra, and enzyme activity. The results showed that the activity and conformation of BCA II changed according to the concentration of TFE. Significant aggregation was observed when BCA II was denatured at TFE concentrations between 10 and 35% (v/v). When the concentration of TFE exceeded 40%, the aggregation of BCA II was not very obvious. The activity of BCA II decreased almost to zero as the TFE concentration reached 26%. The ANS fluorescence spectra indicated the tertiary conformations of BCA II were more stable in solutions with TFE concentrations lower than 15% (v/v) and higher than 40% (v/v). Far-UV CD spectra showed that high concentrations (higher than 25%) of TFE could induce BCA II to form more alpha-helix structures and caused these structures to be in relatively stable states. The native conformation of BCA II being destroyed after its inactivity indicated that the active sites of BCA II is situated in a limited region and has more flexibility than the whole enzyme molecule.
The effects of zinc on creatine kinase (CK) are very distinctive compared with other bivalent metal ions. Zinc up to 0.1 mM induced increases in CK activity, accompanied by significant hydrophobic surface exposure and increase in alpha-helix content of CK. Zinc over 0.1 mM denatured and inactived CK. In the presence of 0.1 mM zinc, the CK activity was very close to that of the native CK, but its conformation changed greatly. The kinetic courses of CK inactivation and conformational change in the presence of 1 mM zinc were measured to determine apparent rate constants of inactivation and conformational change. Zinc over 0.05 mM induced CK aggregation at 37 degrees C, and the aggregation was dependent on zinc concentration, CK concentration, and temperature. The inactivation and aggregation can be reversed by EDTA. An explanation for CK aggregation induced by zinc is proposed, as well as a mechanism for CK abnormality in Alzheimer's disease.
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