High affinity YY1 binding motifs: identification of two core types (ACAT and CCAT) and distribution of potential binding sites within the human beta globin cluster.

PCR-assisted binding site selection was used to define the sequence characteristics of high affinity YY1 binding sites. Compilation of the sequences of 189 selected oligonucleotides containing high affinity YY1 binding sites revealed two types of core sequence: ACAT and CCAT. ACAT cores were surrounded by other invariant nucleotides, forming the consensus GACATNTT. A search of the 73 kb human beta-like globin cluster with this consensus revealed eight matching motifs, six of which were located within 1-3 kb upstream of the gamma and beta genes. CCAT-type cores were more variable in surrounding sequence context; the consensus VDCCATNWY was found to fit 89% of the selected CCAT-containing oligonucleotides. A search of the human beta globin cluster with CCAT consensus sequences revealed 171 potential YY1 binding sites. Several of these were tested directly in gel shift assays and confirmed as high affinity YY1 binding sites. Finally, a strategy called motif-based phylogenetic analysis was employed to determine which of the 179 total sites are evolutionarily conserved. This analysis permits the detection of functionally conserved binding sites despite sequence differences present between the two species. The 21 conserved sites identified will serve as important starting points in further dissection of the possible role of YY1 in globin gene regulation.     

Determining the DNA sequence elements required for binding integration host factor to two different target sites.

Binding sites for the Escherichia coli protein integration host factor (IHF) include a set of conserved bases that can be summarized by the consensus sequence WATCAANNNNTTR (W is dA or dT, R is dA or dG, and N is any nucleotide). However, additional 5'-proximal bases, whose common feature is a high dA+dT content, are also thought to be required for binding at some sites. We examine the relative contribution of these two sequence elements to IHF binding to the H' and H1 sites in attP of bacteriophage lambda by using the bacteriophage P22-based challenge-phage system. IHF was unable to act as a repressor in the challenge-phage assay at H' sites containing the core consensus element but lacking the dA+dT-rich element. This indicates that both elements are required for IHF to bind to the H' site. In contrast, the core consensus determinant alone is sufficient for IHF binding to the H1 site, which lacks an upstream dA+dT-rich region. Fifty mutants that decreased or eliminated IHF binding to the H1 site were isolated. Sequence analysis showed changes in the bases in the core consensus element only, further indicating that this determinant is sufficient for IHF binding to the H1 site. We found that placement of a dA+dT-rich element upstream of the H1 core consensus element significantly increased the affinity, suggesting that the presence of a dA+dT-rich element enhances IHF binding.     

Sequence and structural requirements for high-affinity DNA binding by the WT1 gene product.

The Wilms' tumor suppressor gene, WT1, encodes a zinc finger polypeptide which plays a key role regulating cell growth and differentiation in the urogenital system. Using the whole-genome PCR approach, we searched murine genomic DNA for high-affinity WT1 binding sites and identified a 10-bp motif 5'GCGTGGGAGT3' which we term WTE). The WTE motif is similar to the consensus binding sequence 5'GCG(G/T)GGGCG3' recognized by EGR-1 and is also suggested to function as a binding site for WT1, setting up a competitive regulatory loop. To evaluate the underlying biochemical basis for such competition, we compared the binding affinities of WT1 and EGR1 for both sequences. WT1 shows a 20- to 30-fold-higher affinity for the WTE sequence compared with that of the EGR-1 binding motif. Mutational analysis of the WTE motif revealed a significant contribution to binding affinity by the adenine nucleotide at the eighth position (5'GCGTGGGAGT3') as well as by the 3'-most thymine (5'GCGTGGGAGT3'), whereas mutations in either flanking nucleotides or other nucleotides in the core sequence did not significantly affect the specific binding affinity. Mutations within WT1 zinc fingers II to IV abolished the sequence-specific binding of WT1 to WTE, whereas alterations within the first WT1 zinc finger reduced the binding affinity approximately 10-fold but did not abolish sequence recognition. We have thus identified a WT1 target, which, although similar in sequence to the EGR-1 motif, shows a 20- to 30-fold-higher affinity for WT1. These results suggest that physiological action of WT1 is mediated by binding sites of significantly higher affinity than the 9-bp EGR-1 binding motif. The role of the thymine base in contributing to binding affinity is discussed in the context of recent structural analysis.     

DNA sequence determinants for binding of transformed Ah receptor to a dioxin-responsive enhancer.

We have utilized gel retardation analysis and DNA mutagenesis to examine the specific interaction of transformed guinea pig hepatic cytosolic TCDD.AhR complex with a dioxin-responsive element (DRE). Sequence alignment of the mouse CYPIA1 upstream DREs has identified a common invariant "core" consensus sequence of TNGCGTG flanked by several variable nucleotides. Competitive gel retardation analysis using a series of DRE oligonucleotides containing single or multiple base substitutions has allowed identification of those nucleotides important for TCDD.AhR.DRE complex formation. A putative TCDD.AhR DNA-binding consensus sequence of GCGTGNNA/TNNNC/G has been derived. The four core nucleotides, CGTG, appear to be critical for TCDD-inducible protein-DNA complex formation since their substitution decreased AhR binding affinity by 100-800-fold; the remaining conserved bases are also important, albeit to a lesser degree (3-5-fold). The 5'-ward thymine, present in the invariant core sequence of all the DREs identified to date, appears not to be involved in DNA binding of the AhR. The results obtained here indicate that although the primary interaction of the TCDD.AhR complex with the DRE occurs with the conserved "core" sequence, nucleotides flanking the core also contribute to the specificity of DRE binding.     

Exploring new strategies for grafting binding peptides onto protein loops using a consensus‐designed tetratricopeptide repeat scaffold

Peptide display approaches, in which peptide epitopes of known binding activities are grafted onto stable protein scaffolds, have been developed to constrain the peptide in its bioactive conformation and to enhance its stability. However, peptide grafting can be a lengthy process requiring extensive computational modeling and/or optimisation by directed evolution techniques. In this study, we show that ultra‐stable consensus‐designed tetratricopeptide repeat (CTPR) proteins are amenable to the grafting of peptides that bind the Kelch‐like ECH‐associated protein 1 (Keap1) onto the loop between adjacent repeats. We explore simple strategies to optimize the grafting process and show that modest improvements in Keap1‐binding affinity can be obtained by changing the composition of the linker sequence flanking either side of the binding peptide.     

Role of hydration in the conformational transitions between unliganded and liganded forms of loop 13 of the Na+/glucose cotransporter 1

SGLT1 as a Na+/glucose cotransporter is inhibited by phlorizin, a phloretin 2'-glucoside that has strong interactions with the C-terminal loop 13 (residues 541-638). Here we investigated the effect of a partial substitution of glycerol for water in the medium on the stability and phlorizin-binding function of loop 13 using fluorescence spectroscopy. Increasing the glycerol concentration promoted an increase in the stability of the protein to urea. The ability of loop 13 to expose hydrophobic surface promoted by phlorizin binding was partially lost in the presence of glycerol (20%). Glycerol also led to a decrease in the phlorizin affinity of loop 13 in solution. Approximately 15 molecules of water were taken up to cover additional surface area (137.7+/-27.9A(2)) upon formation of the loop 13-phlorizin complex. Together these results demonstrate quantitatively that the stability and phlorizin affinity of loop 13 are critically dependent on protein hydration.     

Molecular recognition of 6'-N-5-hexynoate kanamycin A and RNA 1x1 internal loops containing CA mismatches

In our previous study to identify the RNA internal loops that bind an aminoglycoside derivative, we determined that 6'-N-5-hexynoate kanamycin A prefers to bind 1x1 nucleotide internal loops containing C·A mismatches. In this present study, the molecular recognition between a variety of RNAs that are mutated around the C·A loop and the ligand was investigated. Studies show that both loop nucleotides and loop closing pairs affect binding affinity. Most interestingly, it was shown that there is a correlation between the thermodynamic stability of the C·A internal loops and ligand affinity. Specifically, C·A loops that had relatively high or low stability bound the ligand most weakly whereas loops with intermediate stability bound the ligand most tightly. In contrast, there is no correlation between the likelihood that a loop forms a C-A(+) pair at lower pH and ligand affinity. It was also found that a 1x1 nucleotide C·A loop that bound to the ligand with the highest affinity is identical to the consensus site in RNAs that are edited by adenosine deaminases acting on RNA type 2 (ADAR2). These studies provide a detailed investigation of factors affecting small molecule recognition of internal loops containing C·A mismatches, which are present in a variety of RNAs that cause disease.     

The role of RNA structure in the interaction of U1A protein with U1 hairpin II RNA

The N-terminal RNA Recognition Motif (RRM1) of the spliceosomal protein U1A interacting with its target U1 hairpin II (U1hpII) has been used as a paradigm for RRM-containing proteins interacting with their RNA targets. U1A binds to U1hpII via direct interactions with a 7-nucleotide (nt) consensus binding sequence at the 5' end of a 10-nt loop, and via hydrogen bonds with the closing C-G base pair at the top of the RNA stem. Using surface plasmon resonance (Biacore), we have examined the role of structural features of U1hpII in binding to U1A RRM1. Mutational analysis of the closing base pair suggests it plays a minor role in binding and mainly prevents "breathing" of the loop. Lengthening the stem and nontarget part of the loop suggests that the increased negative charge of the RNA might slightly aid association. However, this is offset by an increase in dissociation, which may be caused by attraction of the RRM to nontarget parts of the RNA. Studies of a single stranded target and RNAs with untethered loops indicate that structure is not very relevant for association but is important for complex stability. In particular, breaking the link between the stem and the 5' side of the loop greatly increases complex dissociation, presumably by hindering simultaneous contacts between the RRM and stem and loop nucleotides. While binding of U1A to a single stranded target is much weaker than to U1hpII, it occurs with nanomolar affinity, supporting recent evidence that binding of unstructured RNA by U1A has physiological significance.     

Modulation of Integrin Activation by an Entropic Spring in the β-Knee

We show that the length of a loop in the β-knee, between the first and second cysteines (C1-C2) in integrin EGF-like (I-EGF) domain 2, modulates integrin activation. Three independent sets of mutants, including swaps among different integrin β-subunits, show that C1-C2 loop lengths of 12 and longer favor the low affinity state and masking of ligand-induced binding site (LIBS) epitopes. Shortening length from 12 to 4 residues progressively increases ligand binding and LIBS epitope exposure. Compared with length, the loop sequence had a smaller effect, which was ascribable to stabilizing loop conformation, and not interactions with the α-subunit. The data together with structural calculations support the concept that the C1-C2 loop is an entropic spring and an emerging theme that disordered regions can regulate allostery. Diversity in the length of this loop may have evolved among integrin β-subunits to adjust the equilibrium between the bent and extended conformations at different set points.     

Structural analysis of Shu proteins reveals a DNA binding role essential for resisting damage

The yeast Shu complex, consisting of the proteins Shu1, Shu2, Psy3, and Csm2, maintains genomic stability by coupling post-replication repair to homologous recombination. However, a lack of biochemical and structural information on the Shu proteins precludes revealing their precise roles within the pathway. Here, we report on the 1.9-Å crystal structure of the Psy3-Csm2 complex. The crystal structure shows that Psy3 forms a heterodimer with Csm2 mainly through a hydrophobic core. Unexpectedly, Psy3 and Csm2 share a similar architecture that closely resembles the ATPase core domain of Rad51. The L2 loop present in Psy3 and Csm2 is similar to that of Rad51 and confers the DNA binding activity of the Shu complex. As with Rad51, the Shu complex appears to form a nucleoprotein filament by binding nonspecifically to DNA. Structure-based mutagenesis studies have demonstrated that the DNA binding activity of the Shu complex is essential for repair of the methyl methanesulfonate-induced DNA damage. Our findings provide good foundations for the understanding of the Srs2 regulation by the Shu complex.     

Stepwise construction of triple-helical heparin binding sites using peptide models

The specific localization of the asymmetric form of acetylcholinesterase (AChE) in neuromuscular junctions results from the interaction of its collagen-like tail with heparan sulfate proteoglycans in the synaptic basal lamina. This interaction involves two heparin binding consensus sequences of the form XBBXB, where B is a basic residue, located in the triple-helical collagen tail: GRKGR for the N-terminal site and GKRGK for the C-terminal site. To explore the basis of the higher heparin affinity seen for the C-terminal site vs. the N-terminal site, two homologous series of (Gly-Xaa-Yaa)(8) peptides were constructed to model these triple-helical binding sites. Individual tripeptide units from each heparin binding site were introduced in a stepwise fashion into a Gly-Pro-Hyp framework, until the consensus sequence and its surrounding triplets were recreated. As each additional triplet from the binding site is inserted to replace a host Gly-Pro-Hyp triplet, the triple-helix stability decreases, and the drop in thermal stability is close to that expected if each Gly-X-Y triplet contributed independently to global stability. CD spectroscopy and calorimetry show the stability of these AChE model peptides is increased by addition of heparin, confirming binding to heparin, and the lack of significant enthalpy change indicates the binding is largely electrostatic in nature. Displacement assays measure the strength of the peptide-heparin interaction, and indicate an inverse correlation between the peptide ability to bind heparin and its thermal stability. The model peptides for the C-terminal binding site show a greater heparin affinity than the peptide models for the N-terminal binding site only when residues surrounding the consensus sequence are included.     

Different recognition of DNA modified by aatitumor cisplatin and its clinically ineffective trans isomer by tumor suppressor protein p53

The p53 gene encodes a nuclear phosphoprotein that is biologically activated in response to genotoxic stresses including treatment with anticancer platinum drugs. The DNA binding activity of p53 protein is crucial for its tumor suppressor function. DNA interactions of active wild-type human p53 protein with DNA fragments and oligodeoxyribonucleotide duplexes modified by antitumor cisplatin and its clinically ineffective trans isomer (transplatin) were investigated by using a gel mobility shift assay. It was found that DNA adducts of cisplatin reduced binding affinity of the consensus DNA sequence to p53, whereas transplatin adducts did not. This result was interpreted to mean that the precise steric fit required for the formation and stability of the tetrameric complex of p53 with the consensus sequence cannot be attained, as a consequence of severe conformational perturbations induced in DNA by cisplatin adducts. The results also demonstrate an increase of the binding affinity of p53 to DNA lacking the consensus sequence and modified by cisplatin but not by transplatin. In addition, only major 1,2-GG intrastrand cross-links of cisplatin are responsible for this enhanced binding affinity of p53. The data base on structures of various DNA adducts of cisplatin and transplatin reveals distinctive structural features of 1,2-intrastrand cross-links of cisplatin, suggesting a unique role for this adduct in the binding of p53 to DNA lacking the consensus sequence. The results support the hypothesis that the mechanism of antitumor activity of cisplatin may also be associated with its efficiency to affect the binding affinity of platinated DNA to active p53 protein.     

Mutational analysis of the alpha-1 repeat of the cardiac Na(+)-Ca2+ exchanger

The Na(+)-Ca2+ exchanger contains internal regions of sequence homology known as the alpha repeats. The first region (alpha-1 repeat) includes parts of transmembrane segments (TMSs) 2 and 3 and a linker modeled to be a reentrant loop. To determine the involvement of the reentrant loop and TMS 3 portions of the alpha-1 repeat in exchanger function, we generated a series of mutants and examined ion binding and transport and regulatory properties. Mutations in the reentrant loop did not substantially modify transport properties of the exchanger though the Hill coefficient for Na+ and the rate of Na(+)-dependent inactivation were decreased. Mutations in TMS 3 had more striking effects on exchanger activity. Of mutations at 10 positions, 3 behaved like the wild-type exchanger (V137C, A141C, M144C). Mutants at two other positions expressed no activity (Ser139) or very low activity (Gly138). Six different mutations were made at position 143; only N143D was active, and it displayed wild-type characteristics. The highly specific requirement for an asparagine or aspartate residue at this position may indicate a key role for Asn143 in the transport mechanism. Mutations at residues Ala140 and Ile147 decreased affinity for intracellular Na+, whereas mutations at Phe145 increased Na+ affinity. The cooperativity of Na+ binding was also altered. In no case was Ca2+ affinity changed. TMS 3 may form part of a site that binds Na+ but not Ca2+. We conclude that TMS 3 is involved in Na+ binding and transport, but previously proposed roles for the reentrant loop need to be reevaluated.     

The yeast protein encoded by PUB1 binds T-rich single stranded DNA.

We have characterized binding activities in yeast which recognise the T-rich strand of the yeast ARS consensus element and have purified two of these to homogeneity. One (ACBP-60) is detectable in both nuclear and whole cell extracts, while the other (ACBP-67) is apparent only after fractionation of extracts by heparin-sepharose chromatography. The major binding activity detected in nuclear extracts was purified on a sequence-specific DNA affinity column as a single polypeptide with apparent mobility of 60kDa (ACBP-60). This protein co-fractionates with nuclei, is present at several thousand copies per cell and has a Kd for the T-rich single strand of the ARS consensus between 10(-9) and 10(-10) M. Competition studies with simple nucleic acid polymers show that ACBP-60 has marginally higher affinity for poly dT30 than for a 30 nt oligomer containing the T-rich strand of ARS 307, and approximately 10 fold higher affinity for poly rU. Internal sequence information of purified p60 reveals identity with the open reading frames of genes PUB1 and RNP1 which encode polyuridylate binding protein(s). The second binding activity, ACBP-67, also binds specifically to the T-rich single strand of the ARS consensus, but with considerably lower affinity than ACBP-60. Peptide sequence reveals that the 67kDa protein is identical to the major polyA binding protein in yeast, PAB1.