The structure of the Ce(III)-angiotensin II complex as obtained from NMR data and molecular dynamics calculations

Angiotensin II is shown by nuclear magnetic resonance (NMR) to form a complex in water at pH 4.0 with cerium(III), the ideal paramagnetic probe for Ca(2+). Paramagnetic shifts induced by the metal were used for the determination of dissociation constant and complex stoichiometry. ROESY cross-peaks and 3 J(HN-H)(alpha) coupling constants were converted into distance and angular constraints to determine the structure of the complex by molecular dynamics using the simulated annealing protocol. The complex is kinetically labile and involves the Asp-1 side chain and the Phe-8 terminal carboxylates as binding groups resembling a hairpin which has been suggested as a possible biologically active structure.     

The N-terminal region of cystatin A (stefin A) binds to papain subsequent to the two hairpin loops of the inhibitor. Demonstration of two-step binding by rapid-kinetic studies of cystatin A labeled at the N-terminus with a fluorescent reporter group

The three-dimensional structures of cystatins, and other evidence, suggest that the flexible N-terminal region of these inhibitors may bind to target proteinases independent of the two rigid hairpin loops forming the remainder of the inhibitory surface. In an attempt to demonstrate such two-step binding, which could not be identified in previous kinetics studies, we introduced a cysteine residue before the N-terminus of cystatin A and labeled this residue with fluorescent probes. Binding of AANS- and AEDANS-labeled cystatin A to papain resulted in approximately 4-fold and 1.2-fold increases of probe fluorescence, respectively, reflecting the interaction of the N-terminal region with the enzyme. Observed pseudo-first-order rate constants, measured by the loss of papain activity in the presence of a fluorogenic substrate, for the reaction of the enzyme with excess AANS-cystatin A increased linearly with the concentration of the latter. In contrast, pseudo-first-order rate constants, obtained from measurements of the change of probe fluorescence with either excess enzyme or labeled inhibitor, showed an identical hyperbolic dependence on the concentration of the reactant in excess. This dependence demonstrates that the binding occurs in two steps, and implies that the labeled N-terminal region of cystatin A interacts with the proteinase in the second step, subsequent to the hairpin loops. The comparable affinities and dissociation rate constants for the binding of labeled and unlabeled cystatin A to papain indicate that the label did not appreciably perturb the interaction, and that unlabeled cystatin therefore also binds in a similar two-step manner. Such independent binding of the N-terminal regions of cystatins to target proteinases after the hairpin loops may be characteristic of most cystatin-proteinase reactions.     

Interactions of hairpin oligo-2'-O-methylribonucleotides containing methylphosphonate linkages with HIV TAR RNA

Methylphosphonate-modified oligo-2'-O-methylribonucleotides 15-20 nucleotides (nt) in length were prepared whose sequences are complementary to the 5' and 3' sides of the upper hairpin of HIV trans-acting response element (TAR) RNA. These anti-TAR oligonucleotides (ODNs) form stable hairpins whose melting temperatures (Tm) range from 55 degrees C to 80 degrees C. Despite their rather high thermal stabilities, the hairpin oligo-2'-O-methylribonucleotides formed very stable complexes with TAR RNA, with dissociation constants in the nanomolar concentration range at 37 degrees C. The affinities of the hairpin oligomers for TAR RNA were influenced by the positions of the methylphosphonate linkages. The binding affinity was reduced approximately 17-fold by the presence of two methylphosphonate linkages in the TAR loop complementary region (TLCR) of the oligomer, whereas methylphosphonate linkages outside this region increased binding affinity approximately 3-fold. The configurations of the methylphosphonate linkages in the TLCR also affected binding affinity, with the RpRp isomer showing significantly higher binding than the SpSp isomer. In addition to serving as probes of the interactions between the oligomer and TAR RNA, the presence of the methylphosphonate linkages in combination with the hairpin structure increases the resistance of these oligomers to degradation by exonucleases found in mammalian serum. The combination of high binding affinity and nuclease resistance of the hairpin ODNs containing methylphosphonate linkages suggests their potential utility as antisense compounds.     

High-resolution assessment of protein DNA binding affinity and selectivity utilizing a fluorescent intercalator displacement (FID) assay

Protein titration displacement of ethidium bromide bound to hairpin deoxyoligonucleotides containing any sequence of interest provides a well-defined titration curve (measuring the loss of fluorescence derived from the DNA bound ethidium bromide) that provides both absolute binding constants (K(a)) and stoichiometry of binding. This use of a fluorescent intercalator displacement (FID) assay for establishing protein DNA binding affinity and selectivity is demonstrated with the examination of the LEF-1 HMG domain binding to hairpin deoxyoligonucleotides containing its commonly accepted consensus sequence 5'-CTTTGWW (W=A or T) and those modified (5'-CTNTGWW) to examine sequences implicated in early studies (5'-CTNTG). The effectiveness of the FID assay coupled with its technically non-demanding experimental use makes it an attractive alternative or complement to selection screening, footprinting or affinity cleavage, and electrophoretic mobility shift assays for detecting, characterizing, and quantitating protein DNA binding affinity and selectivity.     

Glycyl-tRNA Synthetase as a Potential Universal Regulator of Translation Initiation at IRES-I

A full analysis has been conducted of the sequences and secondary structures of viral type-I or related IRESs identified in all of the elements that correspond to the previously described minimal fragment of the enterovirus C IRES, which mimics the glycine tRNA anticodon hairpin in the IRES structure and is necessary for the specific binding of glycyl—tRNA synthetase. Experiments on human glycyl—tRNA synthetase binding with the mRNA fragments of several taxonomically distant viruses showed that the binding constants of these complexes are similar. These results indicate that the regulation of translation initiation via glycyl—tRNA synthetase must be a universal mechanism for these viruses and the corresponding parts of their mRNAs must have similar spatial structures. Furthermore, at least one additional mRNA hairpin with the glycyl anticodon loop has been found in all analyzed viral type-I IRESs. It seems plausible that this extra hairpin is associated with the second RNA-binding site of the glycyl—tRNA synthetase dimer and stabilizes its complex with the viral mRNA.     

Kinetic analysis of the nicking and hairpin formation steps in V(D)J recombination

The complete cleavage phase of V(D)J recombination includes four phases: binding of the active RAG complexes to the 12- or 23-signals, nicking of the signals, synapsis of the two signals, and hairpin formation at both signals concurrently. We have done time courses for the complete cleavage phase of the V(D)J recombination reaction and quantitated the amount of active RAG enzyme. We have also formulated a kinetic model for the binding, nicking, synapsis, and hairpin formation phases. We have utilized free solution enzymatic measurements for the binding and nicking phases as we do mathematical simulations of the kinetic model. This permits iteration of rate constants for the synapsis and hairpin formation phases until the model fits the observed overall cleavage time course. This process yields a rate constant for the hairpin formation that is 0.004 min(-1), which corresponds to an average catalytic cycle time of 250 min. This value is exceedingly close to a measured value of this constant that relied on wash-out of an inhibitory cofactor. The agreement indicates that this is likely to be the rate of the hairpin step over a wide range of range of conditions and irrespective of the DNA sequence of the V, D or J coding end located adjacent to the signal. These findings indicate that, under optimal in vitro conditions, the core RAG proteins carry out nicking at a rate which is nearly 150-fold faster than hairpin formation. The physiologic implications of this and other kinetic inferences of these time courses are discussed.     

The Escherichia coli DEAD protein DbpA recognizes a small RNA hairpin in 23S rRNA

The Escherichia coli DEAD protein DbpA is an RNA-specific ATPase that is activated by a 153-nt fragment within domain V of 23S rRNA. A series of RNA subfragments and sequence changes were used to identify the recognition elements of this RNA-protein interaction. Reducing the size of the fully active 153-nt RNA yields compromised substrates in which both RNA and ATP binding are weakened considerably without affecting the maximal rate of ATP hydrolysis. All RNAs that stimulate ATPase activity contain hairpin 92 of 23S rRNA, which is known to interact with the 3' end of tRNAs in the ribosomal A-site. RNAs with base mutations within this hairpin fail to activate ATP hydrolysis, suggesting that it is a critical recognition element for DbpA. Although the isolated hairpin fails to activate DbpA, RNAs with an extension of approximately 15 nt on either the 5' or 3' side of hairpin 92 elicit full ATPase activity. These results suggest that the binding of DbpA to RNA requires sequence-specific interactions with hairpin 92 as well as nonspecific interactions with the RNA extension. A model relating the RNA binding and ATPase activities of DbpA is presented.     

Nucleotide-sequence-specific and non-specific interactions of T4 DNA polymerase with its own mRNA

The DNA-binding DNA polymerase (gp43) of phage T4 is also an RNA-binding protein that represses translation of its own mRNA. Previous studies implicated two segments of the untranslated 5′-leader of the mRNA in repressor binding, an RNA hairpin structure and the adjacent RNA to the 3′ side, which contains the Shine–Dalgarno sequence. Here, we show by in vitro gp43–RNA binding assays that both translated and untranslated segments of the mRNA contribute to the high affinity of gp43 to its mRNA target (translational operator), but that a Shine–Dalgarno sequence is not required for specificity. Nucleotide sequence specificity appears to reside solely in the operator’s hairpin structure, which lies outside the putative ribosome-binding site of the mRNA. In the operator region external to the hairpin, RNA length rather than sequence is the important determinant of the high binding affinity to the protein. Two aspects of the RNA hairpin determine specificity, restricted arrangement of purine relative to pyrimidine residues and an invariant 5′-AC-3′ in the unpaired (loop) segment of the RNA structure. We propose a generalized structure for the hairpin that encompasses these features and discuss possible relationships between RNA binding determinants of gp43 and DNA binding by this replication enzyme.     

Interaction of the dimeric form of retroviral RNA with paromonycin and magnesium as revealed using 2-aminopurine fluorescence

Studying the dimeric RNA structural organization is a step toward the understanding of retroviral genomic RNA dimerization. A kissing loop dimer is rearranged into an extended dimer during maturation of the virus particle. The extended dimer formation may be inhibited by ligands interacting with the RNA kissing loop dimer. A study was made of the interaction of dimeric RNA with paromomycin and magnesium ions. RNA dimers were formed from two hairpin RNAs having complementary sequences in the loop. The structural features of RNA dimers and the influence of the ligands were inferred from the fluorescence of 2-aminopurine (2-AP) incorporated in one of the two RNA hairpin sequences. As dimeric RNA interacted with paromomycin, 2-AP fluorescence increased. The increase was explained by a flipping of the fluorescent base out of the RNA structure. The binding constants and stoichiometry were estimated for dimeric RNA binding with paromomycin. An RNA dimer was found to interact with two paromomycin molecules; the binding constant was approximately the same (about 3 × 10⁵ M⁻¹) for both types of dimers. It was observed that the antibiotic and Mg²⁺ ions compete for binding to the hairpin RNA dimer and that one paromomycin molecule is displaced by one Mg²⁺ ion.     

Importance of the second binding loop and the C-terminal end of cystatin B (stefin B) for inhibition of cysteine proteinases.

The importance of residues in the second hairpin loop and the C-terminal end of mammalian cystatin B for binding of proteinases was elucidated by mutagenesis of the bovine inhibitor. Bovine cystatin B was modeled onto the crystal structure of the human inhibitor in complex with papain with minimal structural changes. Substitution of the two deduced contact residues in the second hairpin loop, Leu-73 and His-75, with Gly resulted in appreciably reduced affinities for papain and cathepsins H and B. These losses indicated that the two residues together contribute 20-30% of the free energy of binding of cystatin B to these enzymes and that Leu-73 is responsible for most of this contribution. In contrast, the small decrease in the affinity for cathepsin L suggested that the second hairpin loop is less important for inhibition of this proteinase. Replacement of the contact residue in the C-terminal end, Tyr-97, with Ala resulted in losses in affinity for papain and cathepsins L and H that were consistent with Tyr-97 contributing 6-12% of the energy of binding of cystatin B to these enzymes. However, this substitution minimally affected the affinity for cathepsin B, indicating that the C-terminal end is of limited importance for binding of this proteinase. All affinity decreases were due predominantly to increased dissociation rate constants. These results show that both the second hairpin loop and the C-terminal end of cystatin B contribute to anchoring the inhibitor to target proteinases, each of the two regions interacting with a different domain of the enzyme. However, the relative contributions of these two interactions vary with the proteinase.     

Transmembrane insertion of the Colicin Ia hydrophobic hairpin

Colicin Ia is a bactericidal protein that forms voltage-dependent, ion-conducting channels, both in the inner membrane of target bacteria and in planar bilayer membranes. Its amino acid sequence is rich in charged residues, except for a hydrophobic segment of 40 residues near the carboxyl terminus. In the crystal structure of colicin Ia and related colicins, this segment forms an α-helical hairpin. The hydrophobic segment is thought to be involved in the initial association of the colicin with the membrane and in the formation of the channel, but various orientations of the hairpin with respect to the membrane have been proposed. To address this issue, we attached biotin to a residue at the tip of the hydrophobic hairpin, and then probed its location with the biotin-binding protein streptavidin, added to one side or the other of a planar bilayer. Streptavidin added to the same side as the colicin prevented channel opening. Prior addition of streptavidin to the opposite side protected channels from this effect, and also increased the rate of channel opening; it produced these effects even before the first opening of the channels. These results suggest a model of membrane association in which the colicin first binds with the hydrophobic hairpin parallel to the membrane; next the hairpin inserts in a transmembrane orientation; and finally the channel opens. We also used streptavidin binding to obtain a stable population of colicin molecules in the membrane, suitable for the quantitative study of voltage-dependent gating. The effective gating charge thus determined is pH-independent and relatively small, compared with previous results for wild-type colicin Ia. Received: 12 November 1996/Revised: 23 January 1997     

Structural basis of pyrimidine specificity in the MS2 RNA hairpin-coat-protein complex.

We have determined the X-ray structures of six MS2 RNA hairpin-coat-protein complexes having five different substitutions at the hairpin loop base -5. This is a uracil in the wild-type hairpin and contacts the coat protein both by stacking on to a tyrosine side chain and by hydrogen bonding to an asparagine side chain. The RNA consensus sequence derived from coat protein binding studies with natural sequence variants suggested that the -5 base needs to be a pyrimidine for strong binding. The five -5 substituents used in this study were 5-bromouracil, pyrimidin-2-one, 2-thiouracil, adenine, and guanine. The structure of the 5-bromouracil complex was determined to 2.2 A resolution, which is the highest to date for any MS2 RNA-protein complex. All the complexes presented here show very similar conformations, despite variation in affinity in solution. The results suggest that the stacking of the -5 base on to the tyrosine side chain is the most important driving force for complex formation. A number of hydrogen bonds that are present in the wild-type complex are not crucial for binding, as they are missing in one or more of the complexes. The results also reveal the flexibility of this RNA-protein interface, with respect to functional group variation, and may be generally applicable to other RNA-protein complexes.     

Foldase function of the cathepsin S proregion is strictly based upon its domain structure

Folding of cathepsin S, like other cathepsin L-like proteases, depends on its proregion. The major part of the proregion forms a small domain distal from the catalytic centre, suggesting function(s) beyond active-site shielding. Using an optimised in vitro trans-refolding assay, we compared reactivation of denatured cathepsin S by the genuine propeptide, wild-type and ten selected mutants. Including structural data and binding constants, we identified the prodomain core and the hairpin region to be important for the foldase function.     

A study of the thermophilic ribosomal protein S7 binding to the truncated S12-S7 intercistronic region provides more insight into the mechanism of regulation of the str operon of E. coli(1).

A study of the ability of His6-tagged ribosomal protein S7 of Thermus thermophilus to interact with the truncated S12-S7 intercistronic region of str mRNA of Escherichia coli has been described. A minimal S7 binding mRNA fragment is a part of the composite hairpin, with the termination codon of the S12 cistron on one side and the initiation codon of the next S7 cistron on the other. It has a length in the range of 63-103 nucleotides. The 63 nucleotide mRNA fragment, which corresponds to a putative S7 binding site, binds very poorly with S7. Tight RNA structure models, which behave as integral systems and link the S7 binding site with the translational regulation region of the hairpin, are suggested. This observation provides more insight into the mechanism of S7-directed autogenous control of translational coupling of str mRNA.     

Solution structure of domain 5 of a group II intron ribozyme reveals a new RNA motif

Domain 5 (D5) is the central core of group II intron ribozymes. Many base and backbone substituents of this highly conserved hairpin participate in catalysis and are crucial for binding to other intron domains. We report the solution structures of the 34-nucleotide D5 hairpin from the group II intron ai5 gamma in the absence and presence of divalent metal ions. The bulge region of D5 adopts a novel fold, where G26 adopts a syn conformation and flips down into the major groove of helix 1, close to the major groove face of the catalytic AGC triad. The backbone near G26 is kinked, exposing the base plane of the adjacent A-U pair to the solvent and causing bases of the bulge to stack intercalatively. Metal ion titrations reveal strong Mg(2+) binding to a minor groove shelf in the D5 bulge. Another distinct metal ion-binding site is observed along the minor groove side of the catalytic triad, in a manner consistent with metal ion binding in the ribozyme active site.     

Structural basis for type II membrane protein binding by ERM proteins revealed by the radixin-neutral endopeptidase 24.11 (NEP) complex

ERM (Ezrin/Radixin/Moesin) proteins mediate formation of membrane-associated cytoskeletons by simultaneously binding actin filaments and the C-terminal cytoplasmic tails of adhesion molecules (type I membrane proteins). ERM proteins also bind neutral endopeptidase 24.11 (NEP), a type II membrane protein, even though the N-terminal cytoplasmic tail of NEP possesses the opposite peptide polarity to that of type I membrane proteins. Here, we determined the crystal structure of the radixin FERM (Four point one and ERM) domain complexed with the N-terminal NEP cytoplasmic peptide. In the FERM-NEP complex, the amphipathic region of the peptide forms a beta strand followed by a hairpin that bind to a shallow groove of FERM subdomain C. NEP binding is stabilized by beta-beta interactions and docking of the NEP hairpin into the hydrophobic pocket of subdomain C. Whereas the binding site of NEP on the FERM domain overlaps with the binding site of intercellular adhesion molecule (ICAM)-2, NEP lacks the Motif-1 sequence conserved in ICAM-2 and related adhesion molecules. The NEP hairpin, although lacking the typical inter-chain hydrogen bond but is stabilized by hydrogen bonds with the main chain and side chains of subdomain C, directs the C-terminal basic region of the NEP peptide away from the groove and toward the membrane. The overlap of the binding sites on subdomain C for NEP and Motif-1 adhesion molecules such as CD44 provides the structural basis for the suppression of cell adhesion through interaction between NEP and ERM proteins.     

S4-alpha mRNA translation regulation complex. II. Secondary structures of the RNA regulatory site in the presence and absence of S4

The secondary structure of the Escherichia coli alpha mRNA leader sequence has been determined using nucleases specific for single- or double-stranded RNA. Three different length alpha RNA fragments were studied at 0 degrees C and 37 degrees C. A very stable eight base-pair helix forms upstream from the ribosome initiation site, defining a 29 base loop. There is evidence for base-pairing between nucleotides within this loop and for a "pseudo-knot" interaction of some loop bases with nucleotides just 3' to the initiation codon, forming a region of complex structure. A weak helix also pairs sequences near the 5' terminus of the alpha mRNA with bases near the Shine-Dalgarno sequence. Affinity constants for the translational repressor S4 binding different length alpha mRNA fragments indicate that most of the S4 recognition features must be contained within the main helix and hairpin regions. Binding of S4 to the alpha mRNA alters the structure of the 29 base hairpin region, and probably melts the weak pairing between the 5' and 3' termini of the leader. The pseudo-knot structure and the conformational changes associated with it provide a link between the structures of the S4 binding site and the ribosome binding site. The alpha mRNA may therefore play an active role in mediating translational repression.     

Alpha-diaminobutyric acid-linked hairpin polyamides

A hairpin polyamide-chlorambucil conjugate linked by alpha-diaminobutyric acid (alpha-DABA) has been shown to have interesting biological properties in cellular and small animal models. Remarkably, this new class of hairpin polyamides has not been previously characterized with regard to energetics and sequence specificity. Herein we present a series of pyrrole-imidazole hairpin polyamides linked by alpha-DABA and compare them to polyamides containing the standard gamma-DABA turn unit. The alpha-DABA hairpins have overall decreased binding affinities. However, alpha-DABA polyamide-chlorambucil conjugates are sequence-specific DNA alkylators with increased specificities. Affinity cleavage studies of alpha-DABA polyamide-EDTA conjugates confirmed their preference for binding DNA in a forward hairpin conformation. In contrast, an unsubstituted glycine-linked polyamide prefers to bind in an extended binding mode. Thus, substitution on the turn unit locks the alpha-DABA polyamide into the forward hairpin binding motif.