Free-energy linkage between folding and calcium binding in EF-hand proteins

Troponin is the singular Ca²⁺-sensitive protein in the contraction of vertebrate striated muscles. Troponin C (TnC), the Ca²⁺-binding subunit of the troponin complex, has two distinct domains, C and N, which have different properties despite their extensive structural homology. In this work, we analyzed the thermodynamic stability of the isolated N-domain of TnC using a fluorescent mutant with Phe 29 replaced by Trp (F29W/N-domain, residues 1-90). The complete unfolding of the N-domain of TnC in the absence or presence of Ca²⁺ was achieved by combining high hydrostatic pressure and urea, a maneuver that allowed us to calculate the thermodynamic parameters (ΔV and ΔG_atm). In this study, we propose that part of the affinity for Ca²⁺ is contributed by the free-energy change of folding of the N- and C-domains that takes place when Ca²⁺ binds. The importance of the free-energy change for the structural and regulatory functions of the TnC isolated domains was evaluated. Our results shed light on how the coupling between folding and ion binding contributes to the fine adjustment of the affinity for Ca²⁺ in EF-hand proteins, which is crucial to function.     

Self-complementarity within proteins: bridging the gap between binding and folding

Complementarity, in terms of both shape and electrostatic potential, has been quantitatively estimated at protein-protein interfaces and used extensively to predict the specific geometry of association between interacting proteins. In this work, we attempted to place both binding and folding on a common conceptual platform based on complementarity. To that end, we estimated (for the first time to our knowledge) electrostatic complementarity (Em) for residues buried within proteins. Em measures the correlation of surface electrostatic potential at protein interiors. The results show fairly uniform and significant values for all amino acids. Interestingly, hydrophobic side chains also attain appreciable complementarity primarily due to the trajectory of the main chain. Previous work from our laboratory characterized the surface (or shape) complementarity (Sm) of interior residues, and both of these measures have now been combined to derive two scoring functions to identify the native fold amid a set of decoys. These scoring functions are somewhat similar to functions that discriminate among multiple solutions in a protein-protein docking exercise. The performances of both of these functions on state-of-the-art databases were comparable if not better than most currently available scoring functions. Thus, analogously to interfacial residues of protein chains associated (docked) with specific geometry, amino acids found in the native interior have to satisfy fairly stringent constraints in terms of both Sm and Em. The functions were also found to be useful for correctly identifying the same fold for two sequences with low sequence identity. Finally, inspired by the Ramachandran plot, we developed a plot of Sm versus Em (referred to as the complementarity plot) that identifies residues with suboptimal packing and electrostatics which appear to be correlated to coordinate errors.     

Concordant divergence in proteins and mitochondrial DNA between two vole species in the genusClethrionomys

The bank vole (Clethrionomys glareolus) and the northern red-backed vole (C. rutilus) are two closely related species where interspecific crosses result in fertile female but sterile male offspring. Mitochondrial DNA (mtDNA) fromC. rutilus has passed the species barrier and is found inC. glareolus from northern Fennoscandia. The present report shows that the genetic distance between the two species, calculated from enzyme data (Nei'sD), is 0.64. Isoelectric focusing of muscle proteins resolved around 55 bands, of which each species had 6 or 7 bands not present in the other species. Sequence divergence of mtDNA from the two species is 13.9%. A comparison between protein and mtDNA distances in other species pairs reveals a high correlation between the two measures, indicating that differences in mtDNA between taxa are not random when compared to divergence in protein-coding nuclear genes. The relationship between genetic divergence in proteins and that in mtDNA betweenClethrionomys glareolus andC. rutilus is similar to that found in other species pairs. It is also shown that despite large differences on the protein level it is still, in some cases, possible for species pairs to produce fertile hybrid females.This study was sponsored by the Swedish Natural Science Research Council, the Erik Philip-Sörensen Foundation, and the Nilsson-Ehle Foundation.     

A single spacer nucleotide determines the specificities of two mRNA regulatory proteins

Regulation of messenger RNA is crucial in many contexts, including development, memory and cell growth. The 3' untranslated region is a rich repository of regulatory elements that bind proteins and microRNAs. Here we focus on PUF proteins, an important family of mRNA regulatory proteins crucial in stem-cell proliferation, pattern formation and synaptic plasticity. We show that two Caenorhabditis elegans PUF proteins, FBF and PUF-8, differ in RNA-binding specificity. FBF requires the presence of a single 'extra' nucleotide in the middle of an eight-nucleotide site, whereas PUF-8 requires its absence. A discrete protein segment is responsible for the difference. We propose that a structural distortion in the central region of FBF imposes the requirement for the additional nucleotide and that this mode of PUF specificity may be common. We suggest that new specificities can be designed and selected using the PUF scaffold.     

Coupling of folding and binding for unstructured proteins

There are now numerous examples of proteins that are unstructured or only partially structured under physiological conditions and yet are nevertheless functional. Such proteins are especially prevalent in eukaryotes. In many cases, intrinsically disordered proteins adopt folded structures upon binding to their biological targets. Many new examples of coupled folding and binding events have been reported recently, providing new insights into mechanisms of molecular recognition.     

DNA recognition by the brinker repressor--an extreme case of coupling between binding and folding

The Brinker (Brk) nuclear repressor is a major element of the Drosophila Decapentaplegic morphogen signaling pathway. Its N-terminal part has weak homology to the Antennapedia homeodomain and binds to GC-rich DNA sequences. We have investigated the conformation and dynamics of the N-terminal 101 amino acid residues of Brk in the absence and in the presence of cognate DNA by solution NMR spectroscopy. In the absence of DNA, Brk is unfolded and highly flexible throughout the entire backbone. Addition of cognate DNA induces the formation of a well-folded structure for residues R46 to R95. This structure consists of four helices forming a helix-turn-helix motif that differs from homeodomains, but has similarities to the Tc3 transposase, the Pax-6 Paired domain, and the human centromere-binding protein. The GC-rich DNA recognition can be explained by specific major groove hydrogen bonds from the N-terminal end of helix alpha3. The transition from a highly flexible, completely unfolded conformation in the absence of DNA to a well-formed structure in the complex presents a very extreme case of the "coupling of binding and folding" phenomenon.     

A comparison of the different DNA binding specificities of the bZip proteins C/EBP and GCN4.

The bZip proteins GCN4 and C/EBP differ in their DNA binding specificities: GCN4 binds well to the pseudopalindromic AP1 site 5'-A4T3G2A1C0T1C2'A3'T4'-3' and to the palindromic ATF/CREB sequence 5'-A4T3G2A1-C0*G0'T1'C2'A3'T4'-3'; C/EBP preferentially recognizes the palindromic sequence 5'-A4T3T2G1C0*G0'C1'A2'-A3'T4'-3'. According to the X-ray structures of GCN4-DNA complexes, five residues of the basic region of GCN4 are involved in specific base contacts: asparagine -18, alanine -15, alanine -14, serine -11 and arginine -10 (numbered relative to the start point of the leucine zipper, which we define as +1). In the basic region of C/EBP position -14 is occupied by valine instead of alanine, the other four residues being identical. Here we analyse the role of valine -14 in C/EBP-DNA complex formation. Starting from a C/EBP-GCN4 chimeric bZip peptide which displays C/EBP specificity, we systematically mutated position -14 of its basic region and characterized the DNA binding specificities of the 20 possible different peptides by gel mobility shift assays with various target sites. We present evidence that valine -14 of C/EBP interacts more strongly with thymine 2 than with cytosine 1' of the C/EBP binding site, unlike the corresponding alanine -14 of GCN4, which exclusively contacts thymine 1' of the GCN4 binding sites.     

Alternatively spliced transcripts of the Drosophila tramtrack gene encode zinc finger proteins with distinct DNA binding specificities.

A protein present in nuclear extracts of Drosophila embryos binds multiple sites in the promoter and genetically defined autoregulatory element of the pair-rule gene even-skipped (eve). We reported here the isolation of a cDNA encoding this binding activity, the sequence of which identifies it as the 69 kDa zinc finger tramtrack (ttk) protein. As ttk was previously implicated in controlling the expression of another pair-rule gene, fushi tarazu (ftz), our findings suggest that ttk plays a role in the regulation of at least two developmentally important genes. An additional ttk-related cDNA clone was isolated which gives rise to an 88 kDa protein with an alternative set of zinc fingers having a DNA binding specificity distinct from that of the 69 kDa protein. Both proteins were shown to be encoded by the ttk gene through alternative splicing, providing the first example of the use of this mechanism to generate related proteins with distinct DNA binding specificities. Whole mount in situ hybridization analysis revealed different patterns of embryonic expression of the two ttk mRNA isoforms.     

Interaction between UV-damaged DNA binding activity proteins and the c-Abl tyrosine kinase

The c-Abl tyrosine kinase is activated by some forms of DNA damage, including ionizing radiation, but not UV radiation. The functions of this activation in the damage response pathways remain obscure. To identify potential targets of c-Abl kinase, we utilized the yeast two-hybrid system to screen a murine cDNA library. One c-Abl binding protein of particular interest was the large subunit (DDB1) of the heterodimeric complex with UV-damaged DNA binding activity (UV-DDB). This complex binds with high specificity to DNA damaged by UV, is absent in a subset of xeroderma pigmentosum group E cells, and is required for global genomic repair of UV-induced damage. The association of c-Abl with DDB1 required the kinase domain of c-Abl and preserved the interaction between DDB1 and the small subunit (DDB2) of the UV-DDB complex. Significantly, overexpression of c-Abl increased tyrosine phosphorylation of DDB2 and suppressed UV-DDB activity. Conversely, a dominant negative, kinase-deficient allele of c-Abl decreased tyrosine phosphorylation of DDB2 and dramatically stimulated UV-DDB activity. These results suggest that one role of c-Abl may be to negatively regulate UV-DDB activity by phosphorylation of DDB2.     

Heterodimerization between light-regulated and ubiquitously expressed Arabidopsis GBF bZIP proteins.

The promoters of a variety of plant genes are characterized by the presence of a G-box (CCACGTGG) or closely related DNA motifs. These genes often exhibit quite diverse expression characteristics and in many cases the G-box sequence has been demonstrated to be essential for expression. The G-box of the Arabidopsis rbcS-1A gene is bound by a protein, GBF, identified in plant nuclear extracts. Here we report the isolation of three Arabidopsis thaliana cDNA clones encoding GBF proteins referred to as GBF1, GBF2 and GBF3. GBF1 and GBF2 mRNA is present in light and dark grown leaves as well as in roots. In contrast, GBF3 mRNA is found mainly in dark grown leaves and in roots. The deduced amino acid sequences of the three cDNAs indicate that each encodes a basic/leucine zipper protein. In addition, all three proteins are characterized by an N-terminal proline-rich domain. Homodimers of the three proteins specifically recognize the G-box motif, with GBF1 and GBF3 binding symmetrically to this palindromic sequence. In contrast, GBF2 binds to the symmetrical G-box sequence in such a way that the juxtaposition of the protein and the DNA element is clearly asymmetric and hence distinct from that observed for the other two proteins. The fact that GBF1, GBF2 and GBF3 possess both distinct DNA binding properties and expression characteristics prompt us to entertain the notion that these proteins may individually mediate distinct subclasses of expression properties assigned to the G-box. Furthermore, we demonstrate that GBF1, GBF2 and GBF3 heterodimerize and these heterodimers also interact with the G-box, suggesting a potential mechanism for generating additional diversity from these GBF proteins.