The dynamic nature of the four-way junction of the hepatitis C virus IRES

Translation is initiated within the RNA of the hepatitis C virus at the internal ribosome entry site (IRES). The IRES is a 341-nucleotide element that contains a four-way helical junction (IIIabc) as a functionally important element of the secondary structure. The junction has three additional, nonpaired nucleotides at the point of strand exchange on one diagonal. We have studied the global conformation and folding of this junction in solution, using comparative gel electrophoresis and steady-state and time-resolved fluorescence resonance energy transfer. In the absence of divalent metal ions, the junction adopts an extended-square structure, in contrast to perfect four-way RNA junctions, which retain coaxial helical stacking under all conditions. The IIIabc junction is induced to fold on addition of Mg(2+), by pairwise coaxial stacking of arms, into the conformer in which the unpaired bases are located on the exchanging strands. Fluorescence lifetime measurements indicate that in the presence of Mg(2+) ions, the IIIabc junction exists in a dynamic equilibrium comprising approximately equal populations of antiparallel and parallel species. These dynamic properties may be important in mediating interactions between the IRES and the ribosome and initiation factors.     

Metal ion binding and the folding of the hairpin ribozyme

The hairpin ribozyme comprises two formally unpaired loops carried on two arms of a four-way helical RNA junction. Addition of divalent metal ions brings about a conformational transition into an antiparallel structure in which there is an intimate association between the loops to generate the active form of the ribozyme. In this study, we have used fluorescence resonance energy transfer to analyze the global folding of the complete ribozyme, and the simple four-way junction derived from it, over a wide concentration range of divalent and monovalent metal ions. The simple junction undergoes an ion-induced rotation into an antiparallel form. In the presence of a constant background concentration of sodium ions, the magnesium-ion-induced transition is characterized by noncooperative binding with a Hill coefficient n = 1. By contrast, the magnesium-ion-induced folding of the complete ribozyme is more complex, involving two distinct binding phases. The first phase occurs in the micromolar range, and involves the cooperative binding of at least three magnesium ions. This can also be achieved by high concentrations of sodium ions, and is therefore likely to be due to diffuse binding of cations at the junction and the interface of the loop-loop interaction. The second phase occurs in the millimolar range, and can only be induced by divalent metal ions. This transition occurs in response to the noncooperative, site-specific binding of magnesium ions. We observe a good correlation between the extent of ion-induced folding and cleavage activity.     

Cross-adaptation and molecular modeling study of receptor mechanisms common to four taste stimuli in humans

Psychophysical cross-adaptation experiments were performed with two carbohydrates, sucrose (SUC) and fructose (FRU), and two sweeteners, acesulfame-K (MOD) and dulcin (DUL). Seven subjects were asked to match concentrations that elicited the same intensity as a sucrose reference (30 g/l). Cross-adaptation levels were calculated as the ratio of isointense concentrations measured for a given stimulus before and under adaptation. On average, cross-adaptation between SUC and FRU is low and apparently reciprocal. By contrast, cross-adaptation between SUC and MOD is clearly non-reciprocal: SUC adapts MOD significantly (24%, P < 0.005), but MOD fails to adapt SUC (2%, P < 0.79). Significant and reciprocal cross-enhancement is observed between DUL and MOD (approximately -20%, P < 0.03), and also between SUC and DUL (approximately -15%, P < 0.08). In parallel, molecular modeling of the four tastants was performed in order to look for the 12 common binding motifs that were isolated on 14 other tastants in a previous study. SUC and FRU each display 10 out of the 12 binding motifs, whereas DUL and MOD only display four and five distinct motifs respectively and do not have any motif in common. Experimental cross-adaptation levels seem to correlate well with the number of motifs that molecules have in common. FRU and SUC share a majority of binding motifs and correlatively show mutual cross-adaptation. Four motifs of MOD are found among the 10 motifs of SUC, which may explain why SUC cross-adapts MOD but not vice versa. By contrast, DUL and MOD do not share any motif and do not cross- adapt. The various molecular mechanisms that may be responsible for cross-adaptation and/or cross-enhancement are discussed in light of our results.      

Folding of branched RNA species

The global structures of branched RNA species are important to their function. Branched RNA species are defined as molecules in which double-helical segments are interrupted by abrupt discontinuities. These include helical junctions of different orders, and base bulges and loops. Common helical junctions are three- and four-way junctions, often interrupted by mispairs or additional nucleotides. There are many interesting examples of functional RNA junctions, including the hammerhead and hairpin ribozymes, and junctions that serve as binding sites for proteins. The junctions display some common structural properties. These include a tendency to undergo pairwise helical stacking and ion-induced conformational transitions. Helical branchpoints can act as key architectural components and as important sites for interactions with proteins. Copyright 1999 John Wiley & Sons, Inc.     

Global structure of four-way RNA junctions studied using fluorescence resonance energy transfer.

Four-way helical junctions are found widely in natural RNA species. In this study, we have studied the conformation of two junctions by fluorescence resonance energy transfer. We show that the junctions are folded by pairwise coaxial helical stacking, forming one predominant stacking conformer in both examples studied. At low magnesium ion concentrations, the helical axes of both junctions are approximately perpendicular. One junction undergoes a rotation into a distorted antiparallel structure induced by the binding of a single magnesium ion. By contrast, the axes of the four-way junction of the U1 snRNA remain approximately perpendicular under all conditions examined, and we have determined the stacking conformer adopted.     

The evolutionary analysis of the Tnt1 retrotransposon in Nicotiana species reveals the high variability of its regulatory sequences

We studied the evolution of the tobacco Tnt1 retrotransposon by analyzing Tnt1 partial sequences containing both coding domains and U3 regulatory sequences obtained from a number of Nicotiana species. We detected three different subfamilies of Tnt1 elements, Tnt1A, Tnt1B, and Tnt1C, that differ completely in their U3 regions but share conserved flanking coding and LTR regions. U3 divergence between the three subfamilies is found in the region that contains the regulatory sequences that control the expression of the well-characterized Tnt1-94 element. This suggests that expression of the three Tnt1 subfamilies might be differently regulated. The three Tnt1 subfamilies were present in the Nicotiana genome at the time of species divergence, but have evolved independently since then in the different genomes. Each Tnt1 subfamily seems to have conserved its ability to transpose in a limited and different number of Nicotiana species. Our results illustrate the high variability of Tnt1 regulatory sequences. We propose that this high sequence variability could allow these elements to evolve regulatory mechanisms in order to optimize their coexistence with their host genome.      

The solution structure of the four-way DNA junction at low-salt conditions: a fluorescence resonance energy transfer analysis.

The four-way DNA (Holliday) junction is an important postulated intermediate in the process of genetic recombination. Earlier studies have suggested that the junction exists in two alternative conformations, depending upon the salt concentration present. At high salt concentrations the junction folds into a stacked X structure, while at low salt concentrations the data indicate an extended unstacked conformation. The stereochemical conformation of the four-way DNA junction at low salt (low alkali ion concentration and no alkaline earth ions) was established by comparing the efficiency of fluorescence resonance energy transfer (FRET) between donor and acceptor molecules attached pairwise in three permutations to the 5' termini of the duplex arms. A new variation of FRET was implemented based upon a systematic variation of the fraction of donor labeled single strands. The FRET results indicate that the structure of the four-way DNA junction at low salt exists as an unstacked, extended, square arrangement of the four duplex arms. The donor titration measurements made in the presence of magnesium ions clearly show the folding of the junction into the X stacked structure. In addition, the FRET efficiency can be measured. The fluorescence anisotropy of the acceptor in the presence of Mg2+ during donor titrations was also measured; the FRET efficiency can be calculated from the anisotropy data and the results are consistent with the folded, stacked X structure.     

Recombinant antineuraminidase single chain antibody: Expression,characterization, and crystallization in complex with antigen

The variable heavy (VH) and variable light (VL) genes of NC10, a monoclonal antibody with specificity toward N9 neuraminidase (NA), were cloned and sequenced. A single chain Fv (scFv) fragment of NC10, consisting of VH and VL domains joined by a peptide linker, was designed, constructed and expressed in the E. coli expression vector pPOW. The N-terminal secretion signal PelB directed the synthesized protein into the periplasm where it was associated with the insoluble membrane fraction. An octapeptide (FLAG) tail was fused to the C-terminus of the single chain Fv to aid in its detection and remained intact throughout the protein purification process. NC10 scFv was purified by solubilization of the E. coli membrane fraction with guanidinium hydrochloride followed by column chromatography. The purified NC10 scFv showed binding affinity for its antigen, NA, 2-fold lower than that of the parent Fab. The complex between NA and the scFv has been crystallized by the vapor diffusion method. The crystals are tetragonal, space group P42₁2, with unit cell dimensions a = b = 141 Å, c = 218 Å. © 1993 Wiley-Liss, Inc.     

Tetraplex folding of telomere sequences and the inclusion of adenine bases.

Telomeres are required for eukaryotic chromosome stability. They consist of regularly repeating guanine-rich sequences, with a single-stranded 3' terminus. Such sequences have been demonstrated to have the propensity to adopt four-stranded structures based on a tetrad of guanine bases. The formation of an intramolecular foldback tetraplex is associated with markedly increased mobility in polyacrylamide. Most telomeric sequences are based either on a repeat of d(TnGGGG) or d(TnAGGG) sequences. We have used a combination 7-deazaguanine or 7-deaza-adenine substitution, chemical modification and gel electrophoresis to address the following aspects of intramolecular tetraplex formation. (i) Intramolecular tetraplex formation by d(TTTTGGGG)4 sequences is prevented by very low levels of 7-deazaguanine substitution. This confirms the important role of guanine N7 in the formation of the tetraplex. (ii) The sequences d(TTAGGG)4 and d(TTTTAGGG)4 fold into tetraplexes. By contrast, the electrophoretic behaviour of d(TTTTGGGA)4, d(TTTTAGAG)4 and d(TTTTGAGA)4 does not indicate formation of stable intramolecular tetraplexes under available conditions. (iii) Selective 7-deazaguanine and 7-deaza-adenine substitutions in d(TTTTAGGG)4 give results consistent with tetraplex folding by the formation of three G4 tetrads, with the adenine bases formally part of the single-stranded loops, where they probably interact with thymine bases. These results demonstrate that eukaryotic cells appear to have selected just those sequences that can adopt the tetraplex conformation for their telomeres, while those that cannot have been avoided. This suggests that the conformation may be significant in the function of the telomere, such as attachment to nuclear structures.