Cellular activity of Rev response element RNA targeting metallopeptides

The cellular chemistry of metallopeptide complexes designed to target and inactivate an HIV Rev response element (RRE) RNA sequence in vivo has been evaluated by use of an efficient cellular fluorescence assay. Transcribed messenger RNA encoding the green fluorescent protein (GFP) that includes a target RNA sequence is sensitive to cleavage chemistry mediated by metal derivatives of GGH(G) _x TRQARRNRR RRWRERQR (x = 0, 1, 2, 4, 6). This results in a significant decrease in expression of GFP that can be quantified by fluorimetry. Optimal inactivation of the target RRE RNA was achieved with linkers where x = 0 or 1. Neither the Rev control peptide (lacking metal-binding or linker sequences) nor the metal-binding motif alone had any significant effect. Consequently, both the cleavage motif and the RNA targeting motif are essential to promote cellular cleavage of the target RRE RNA. However, target inactivation was also observed in experiments with metal-free peptide, consistent with recruitment of intracellular metal ion by the peptide following cellular uptake, with subsequent cleavage of the RRE target RNA. The RRE RNA cleavage activities of metallopeptide complexes were further confirmed by in vitro experiments and mammalian cell assays.     

Allosteric regulation of a ribozyme activity through ligand-induced conformational change.

An allosteric ribozyme has been designed using the hammerhead ribozyme as the active site and aflavin-specific RNA aptamer as a regulatory site. We constructed six variants with a series of base pairs in the linker region (stem II). Under single turnover conditions, kinetic studies were carried out in the absence and presence of flavin mononucleotide (FMN). Interestingly, FMN addition did not influence the cleavage rate of constructs with a 5-6 bp linker but stimulated the catalytic activity of those bearing a shorter linker. In particular, the apparent k cat of Rz3 increases by approximately 10-fold upon addition of saturating amounts of FMN. To determine the rate constants( K m4and k cat), the ribozyme regulated most effectively by FMN was further investigated. FMN mainly affected the k cat value, reflecting the rate limiting conformational change step of the overall cleavage reaction, depending on helix formation in stem II. Probably, FMN influences the orientation of structures necessary for the cleavage reaction through stem II formation. The result of chemical modification revealed that binding of FMN to the aptamer domain induced the helix formation in stem II required for catalytic activity. Therefore, a specific FMN-mediated allosteric interaction seems to promote a conformational alteration from an open to a closed structure in stem II. The concept of conformational modification in the allosteric effect is consistent with other allosteric enzymes, suggesting that such a conformational change is a fundamental feature of allosteric enzymes in biological systems.     

Structure of the ribozyme substrate hairpin of Neurospora VS RNA: a close look at the cleavage site

The cleavage site of the Neurospora VS RNA ribozyme is located in a separate hairpin domain containing a hexanucleotide internal loop with an A-C mismatch and two adjacent G-A mismatches. The solution structure of the internal loop and helix la of the ribozyme substrate hairpin has been determined by nuclear magnetic resonance (NMR) spectroscopy. The 2 nt in the internal loop, flanking the cleavage site, a guanine and adenine, are involved in two sheared G.A base pairs similar to the magnesium ion-binding site of the hammerhead ribozyme. Adjacent to the tandem G.A base pairs, the adenine and cytidine, which are important for cleavage, form a noncanonical wobble A+-C base pair. The dynamic properties of the internal loop and details of the high-resolution structure support the view that the hairpin structure represents a ground state, which has to undergo a conformational change prior to cleavage. Results of chemical modification and mutagenesis data of the Neurospora VS RNA ribozyme can be explained in context with the present three-dimensional structure.     

Assignment and modeling of the Rev Response Element RNA bound to a Rev peptide using 13C-heteronuclear NMR

Summary The Rev Response Element (RRE) RNA-Rev protein interaction is important for regulation of gene expression in the human immunodeficiency virus. A model system for this interaction, which includes stem IIB of the RRE RNA and an arginine-rich peptide from the RNA-binding domain of Rev, was studied using multidimensional heteronuclear NMR. Assignment of the RNA when bound to the peptide was obtained from NMR experiments utilizing uniformly and specifically ¹³C-labeled RNA. Isotopic filtering experiments on the specifically labeled RNA enabled unambiguous assignment of unusual nonsequential NOE patterns present in the internal loop of the RRE. A three-dimensional model of the RNA in the complex was obtained using restrained molecular dynamics calculations. The internal loop contains two purine-purine base pairs, which are stacked to form one continuous helix flanked by two A-form regions. The formation of a G-G base pair in the internal loop requires an unusual structure of the phosphate backbone. This structural feature is consistent with mutational data as being important for the binding of Rev to the RRE. The G-G base pair may play an important role in opening the normally narrow major groove of A-form RNA to permit binding of the Rev basic domain.     

A multifunctional expression vector for an anti-HIV-1 ribozyme that produces a 5'- and 3'-trimmed trans-acting ribozyme, targeted against HIV-1 RNA, and cis-acting ribozymes that are designed to bind to and thereby sequester trans-activator proteins such as Tat and Rev.

We previously constructed a multiribozyme expression vector by combining cis- and trans-acting ribozymes and we showed that several ribozymes, each directed against a different target in the HIV genome and acting independently in a 'shotgun' manner, markedly increased the efficiency of cleavage of HIV RNA in vitro [Ohkawa et al., Proc. Natl Acad. Sci. USA 90, 11302 (1993)]. However, the cis-acting ribozymes that had trimmed the 5' and 3' ends of each trans-acting ribozyme were designed merely to await for degradation by RNases when they were used in vivo. Since several trans-activator proteins are essential for viral replication of HIV-1, we wondered whether a decoy function could be coupled with the cleavage activity of ribozymes. We therefore introduced the TAR or the RRE sequence into the stem II region of each cis-acting ribozyme. When the activity of each resulting cis-acting ribozyme that had been endowed with the decoy function was examined in vitro, it was found to retain almost full trimming activity. Moreover, cis-acting ribozymes with either the TAR or the RRE sequence were shown to be able to trap Tat or Rev protein successfully. It is, therefore, possible to endow the stem II region with a specific protein-binding function without the loss of ribozyme function. Thus, cis-acting ribozymes, endowed with the decoy function, can first trim the 5' and 3' ends of each trans-acting ribozyme and are then still available for trapping trans-activator proteins possibly prior to their degradation by RNases when they are to be used in vivo. Furthermore, it is also expected that the reduction in production of HIV RNA that is achieved by sequestering the trans-activator proteins might provide the trans-acting ribozymes, targeted to HIV RNA, with a better chance of eliminating the remaining HIV RNA.     

Interaction of structural modules in substrate binding by the ribozyme from Bacillus subtilis RNase P.

The ribozyme from bacterial ribonuclease P recognizes two structural modules in a tRNA substrate: the T stem-loop and the acceptor stem. These two modules are connected through a helical linker. The T stem-loop binds at a surface confined in a folding domain away from the active site. Substrates for the Bacillus subtilis RNase P RNA were previously selected in vitro that are shown to bind comparably well or better than a tRNA substrate. Chemical modification of P RNA-substrate complexes with dimethylsulfate and kethoxal was performed to determine how the P RNA recognizes three in vitro selected substrates. All three substrates bind at the surface known to interact with the T stem-loop of tRNA. Similar to a tRNA, the secondary structure of these substrates contains a helix around the cleavage site and a hairpin loop at the corresponding position of the T stem-loop. Unlike a tRNA, these two structural modules are connected through a non-helical linker. The two structural modules in the tRNA and in the selected substrates bind to two different domains in P RNA. The properties of substrate recognition exhibited by this ribozyme may be exploited to isolate new ribozyme-substrate pairs with interactive structural modules.     

Base and sugar requirements for RNA cleavage of essential nucleoside residues in internal loop B of the hairpin ribozyme: implications for secondary structure.

The hairpin ribozyme is a small self-cleaving RNA that can be engineered for RNA cleavage in trans and has potential as a therapeutic agent. We have used a chemical synthesis approach to study the requirements of hairpin RNA cleavage for sugar and base moieties in residues of internal loop B, an essential region in one of the two ribozyme domains. Individual nucleosides were substituted by either a 2'-deoxy-nucleoside, an abasic residue, or a C3-spacer (propyl linker) and the abilities of the modified ribozymes to cleave an RNA substrate were studied in comparison with the wild-type ribozyme. From these results, together with previous studies, we propose a new model for the potential secondary structure of internal loop B of the hairpin ribozyme.     

小型核酶的结构和催化机理

自然界存在的小型核酶主要有锤头型核酶、发夹型核酶、肝炎δ病毒（HDV）核酶和VS核酶.锤头型核酶由3个短螺旋和1个广义保守的连接序列组成;发夹型核酶的催化中心由两个肩并肩挨着的区域构成;HDV核酶折叠成包含五个螺旋臂（P1～P4）的双结结构;VS核酶由五个螺旋结构组成,这些螺旋结构通过两个连接域连接起来.小型核酶的催化机理与其分子结构密切相关.金属离子或特定碱基都可作为催化反应的关键成分.锤头型核酶的催化必须有金属离子（尤其是二价金属离子）参与,而发夹型核酶则完全不需要金属离子.基因组HDV核酶进行催化时要有金属离子和特定碱基互相配合.     

Conformational heterogeneity at position U37 of an all-RNA hairpin ribozyme with implications for metal binding and the catalytic structure of the S-turn

The hairpin ribozyme is an RNA enzyme that performs site-specific phosphodiester bond cleavage between nucleotides A-1 and G+1 within its cognate substrate. Previous functional studies revealed that the minimal hairpin ribozyme exhibited "gain-of-function" cleavage properties resulting from U39C or U39 to propyl linker (C3) modifications. Furthermore, each "mutant" displayed different magnesium-dependence in its activity. To investigate the molecular basis for these gain-of-function variants, crystal structures of minimal, junctionless hairpin ribozymes were solved in native (U39), and mutant U39C and U39(C3) forms. The results revealed an overall molecular architecture comprising two docked internal loop domains folded into a wishbone shape, whose tertiary interface forms a sequestered active site. All three minimal hairpin ribozymes bound Co(NH(3))(6)(3+) at G21/A40, the E-loop/S-turn boundary. The native structure also showed that U37 of the S-turn adopts both sequestered and exposed conformations that differ by a maximum displacement of 13 A. In the sequestered form, the U37 base packs against G36, and its 2'-hydroxyl group forms a water mediated hydrogen bond to O4' of G+1. These interactions were not observed in previous four-way-junction hairpin ribozyme structures due to crystal contacts with the U1A splicing protein. Interestingly, the U39C and U39(C3) mutations shifted the equilibrium conformation of U37 into the sequestered form through formation of new hydrogen bonds in the S-turn, proximal to the essential nucleotide A38. A comparison of all three new structures has implications for the catalytically relevant conformation of the S-turn and suggests a rationale for the distinctive metal dependence of each mutant.     

Small, efficient hammerhead ribozymes

The hammerhead ribozyme is able to cleave RNA in a sequence-specific manner. These ribozymes are usually designed with four basepairs in helix II, and with equal numbers of nucleotides in the 5′ and 3′ hybridizing arms that bind the RNA substrate on either side of the cleavage site. Here guidelines are given for redesigning the ribozyme so that it is small, but retains efficient cleavage activity. First, the ribozyme may be reduced in size by shortening the 5′ arm of the ribozyme to five or six nucleotides; for these ribozymes, cleavage of short substrates is maximal. Second, the internal double-helix of the ribozyme (helix II) may be shortened to one or no basepairs, forming a miniribozyme or minizyme, respectively. The sequence of the shortened helix+loop II greatly affects cleavage rates. With eight or more nucleotides in both the 5′ and the 3′ arms of a miniribozyme containing an optimized sequence for helix+loop II, cleavage rates of short substrates are greater than for analogous ribozymes possessing a longer helix II. Cleavage of genelength RNA substrates may be best achieved by miniribozymes.     

Optimal self-cleavage activity of the hepatitis delta virus RNA is dependent on a homopurine base pair in the ribozyme core.

A non-Watson-Crick G.G interaction within the core region of the hepatitis delta virus (HDV) antigenomic ribozyme is required for optimal rates of self-cleavage activity. Base substitutions for either one or both G's revealed that full activity was obtained only when both G's were replaced with A's. At those positions, substitutions that generate potential Watson-Crick, G.U, heteropurine, or homopyrimidine combinations resulted in dramatically lower cleavage activity. A homopurine symmetric base pair, of the same type identified in the high-affinity binding site of the HIV RRE, is most consistent with this data. Additional features shared between the antigenomic ribozyme and the Rev binding site in the vicinity of the homopurine pairs suggest some structural similarity for this region of the two RNAs and a possible motif associated with this homopurine interaction. Evidence for a homopurine pair at the equivalent position in a modified form of the HDV genomic ribozyme was also found. With the postulated symmetric pairing scheme, large distortions in the nucleotide conformation, the sugar-phosphate backbone, or both would be necessary to accommodate this interaction at the end of a helix; we hypothesize that this distortion is critical to the structure of the active site of the ribozyme and it is stabilized by the homopurine base pair.     

In vitro selection of hairpin ribozymes activated with short oligonucleotides

We have carried out an in vitro selection to obtain an allosteric hairpin ribozyme, which has cleavage activity in the presence of an exogenous short oligonucleotide as a regulator. Random sequences were inserted in a region corresponding to the hairpin loop of the ribozyme. After 12 rounds of selection, DNA templates were cloned. Of a total of 34 clones, 18 contained the same sequence, and the obtained hairpin ribozymes showed the cleavage activity specifically in the presence of the regulator oligonucleotide. All of the clones contained sequences complementary to the regulator oligonucleotide. The ribozymes with high cleavage activities gained characteristic hairpin loops at the random domain, which were similar to each other. In the absence of the oligonucleotide, the loop domain within the allosteric ribozyme probably forms a slipped hairpin loop, and the complementary sequence, with the regulator oligonucleotide located at the single stranded loop, would allow easy access of the oligonucleotide. The binding of the regulator oligonucleotide triggers a structural change of the hairpin loop to form an active conformation. Furthermore, we constructed an allosteric hammerhead ribozyme by introducing the characteristic hairpin loop. The modified hammerhead ribozyme was also changed to an allosteric ribozyme, which was activated by the addition of the regulator oligonucleotide. The characteristic hairpin loop, which was proved to be regulated by an exogenous oligonucleotide in this report, may be used to control RNA functions in various fields.     

Extension of helix II of an HIV-1-directed hammerhead ribozyme with long antisense flanks does not alter kinetic parameters in vitro but causes loss of the inhibitory potential in living cells.

When designed to cleave a target RNA in trans, the hammerhead ribozyme contains two antisense flanks which form helix I and helix III by pairing with the complementary target RNA. The sequences forming helix II are contained on the ribozyme strand and represent a major structural component of the hammerhead structure. In the case of an inhibitory 429 nucleotides long trans-ribozyme (2as-Rz12) which was directed against the 5'-leader/gag region of the human immunodeficiency virus type 1 (HIV-1), helix II was not pre-formed in the single-stranded molecule. Thus, major structural changes are necessary before cleavage can occur. To study whether pre-formation of helix II in the non-paired 2as-Rz12 RNA could influence the observed cleavage rate in vitro and its inhibitory activity on HIV-1 replication, we extended the 4 base pair helix II of 2as-Rz12 to 6, 10, 21, and 22 base pairs respectively. Limited RNase cleavage reactions performed in vitro at 37 degrees C and at physiological ion strength indicated that a helix II of the hammerhead domain was pre-formed when its length was at least six base pairs. This modification neither affected the association rate with target RNA nor the cleavage rate in vitro. In contrast to this, extension of helix II led to a significantly decreased inhibition of HIV-1 replication in human cells. Together with the finding of others that shortening of helix II to less than two base pairs reduces the catalytic activity in vitro, this observation indicates that the length of helix II in the naturally occurring RNAs with a hammerhead domain is already close or identical to the optimal length for catalytic activity in vitro and in vivo.     

Linkage of a Triple Helix-Forming Oligonucleotide to Amsacrine-4-carboxamide Derivatives Modulates the Sequence-Selectivity of Topoisomerase II-Mediated DNA Cleavage

Abstract

Amsacrine-4-carboxamide-oligonucleotide conjugates were synthesized and studied for their capacity to form DNA triple helices and to alter human topoisomerase II binding and cleavage properties. The intercalating agent was attached to the 3′- or the 5′-end of a 24 nt triple helix-forming oligonucleotide via linkers of different lengths. The stability of these DNA triple helices was investigated by gel retardation and melting temperature studies using a synthetic 70 bp DNA duplex target. The effect of the conjugates on DNA cleavage by topoisomerase II was evaluated using the 70 bp duplex and a 311 bp restriction fragment containing the same triple helix site. The conjugate with the amsacrine derivative linked to the 3′ end of the TFO via a hexaethylene glycol linker modulates the extent of DNA cleavage by topoisomerase II at specific sites.     

RNA-ligand interactions: affinity and specificity of aminoglycoside dimers and acridine conjugates to the HIV-1 Rev response element

Semisynthetic aminoglycoside derivatives may provide a means to selectively target viral RNA sites, including the HIV-1 Rev response element (RRE). The design, synthesis, and evaluation of derivatives based upon neomycin B, kanamycin A, and tobramycin conjugates of 9-aminoacridine are presented. To evaluate the importance of the acridine moiety, a series of dimeric aminoglycosides as well as unmodified "monomeric" aminoglycosides have also been evaluated for their nucleic acid affinity and specificity. Fluorescence-based binding assays that use ethidium bromide or Rev peptide displacement are used to quantify the affinities of these compounds to various nucleic acids, including the RRE, tRNA, and duplex DNA. All the modified aminoglycosides exhibit a high affinity for the Rev binding site on the RRE (K(d) 相似文献   

The loop B domain is physically separable from the loop A domain in the hairpin ribozyme.

In order to understand the catalysis mechanism of the hairpin ribozyme, mutant ribozymes were constructed. The distance between the loop A domain and the loop B domain was extended by inserting various lengths of nucleotide linkers at the hinge region in cis mutants, or the domains were separated physically in a trans mutant. All the mutant ribozymes, including the trans mutant, could cleave substrate RNA at the predicted site. A cis mutant with a single nucleotide insertion exhibited cleavage activity about twice as high as that of the wild-type (wt) ribozyme. The insertion of 2-5 nucleotides (nt) gradually reduced the activity to the level of the wt ribozyme. Insertion of a longer linker, up to 11 nt, resulted in the reduction of activity to one half of that of the wt ribozyme. The ribozyme with a single nucleotide insertion at the hinge region seems to form a more suitable conformation for catalysis by three-dimensional fold-back of the loop B to loop A containing the cleavage site. The trans mutant, in which the A and B domains were physically separated, maintained a significant level of activity, suggesting that both domains are necessary for catalysis, but separable. These results demonstrate that interaction between the A and B domains results in catalysis.     

Computational modeling suggests dimerization of equine infectious anemia virus Rev is required for RNA binding

Background

The lentiviral Rev protein mediates nuclear export of intron-containing viral RNAs that encode structural proteins or serve as the viral genome. Following translation, HIV-1 Rev localizes to the nucleus and binds its cognate sequence, termed the Rev-responsive element (RRE), in incompletely spliced viral RNA. Rev subsequently multimerizes along the viral RNA and associates with the cellular Crm1 export machinery to translocate the RNA-protein complex to the cytoplasm. Equine infectious anemia virus (EIAV) Rev is functionally homologous to HIV-1 Rev, but shares very little sequence similarity and differs in domain organization. EIAV Rev also contains a bipartite RNA binding domain comprising two short arginine-rich motifs (designated ARM-1 and ARM-2) spaced 79 residues apart in the amino acid sequence. To gain insight into the topology of the bipartite RNA binding domain, a computational approach was used to model the tertiary structure of EIAV Rev.

Results

The tertiary structure of EIAV Rev was modeled using several protein structure prediction and model quality assessment servers. Two types of structures were predicted: an elongated structure with an extended central alpha helix, and a globular structure with a central bundle of helices. Assessment of models on the basis of biophysical properties indicated they were of average quality. In almost all models, ARM-1 and ARM-2 were spatially separated by >15 Å, suggesting that they do not form a single RNA binding interface on the monomer. A highly conserved canonical coiled-coil motif was identified in the central region of EIAV Rev, suggesting that an RNA binding interface could be formed through dimerization of Rev and juxtaposition of ARM-1 and ARM-2. In support of this, purified Rev protein migrated as a dimer in Blue native gels, and mutation of a residue predicted to form a key coiled-coil contact disrupted dimerization and abrogated RNA binding. In contrast, mutation of residues outside the predicted coiled-coil interface had no effect on dimerization or RNA binding.

Conclusions

Our results suggest that EIAV Rev binding to the RRE requires dimerization via a coiled-coil motif to juxtapose two RNA binding motifs, ARM-1 and ARM-2.

     

Construction of new ribozymes requiring short regulator oligonucleotides as a cofactor

A hairpin loop and an oligonucleotide bound to the loop form one-half of the pseudoknot structure. We have designed an allosteric hammerhead ribozyme, which is activated by the introduction of this motif by using a short complementary oligonucleotide as a cofactor. Stem II of the hammerhead ribozyme was substituted with a non-self-complementary loop sequence (loop II) to abolish the cleavage activity. The new ribozyme had almost no cleavage activity of the target RNA. However, it exhibited the cleavage activity in the presence of a cofactor oligoribonucleotide, which is complementary to loop II of the ribozyme. The activity is assumed to be derived from the formation of a pseudo-stem structure between the cofactor oligonucleotide and loop II. The structure including the loop may be similar to the pseudo-half-knot structure. The activation efficiencies of the cofactor oligonucleotides were decreased as the lengths of the oligonucleotides increased, and the ribozyme with a longer loop II was more active than that with a short loop II. Oligoribonucleotides with 3'-dangling purine bases served as efficient cofactors of the ribozyme, and a 2'-O-methyloligonucleotide enhanced the cleavage activity of the ribozyme most efficiently, by as much as about 750-fold as compared with that in the absence of the oligonucleotide. Cofactor oligonucleotides with a cytidine base at the 3'-end also activated a ribozyme with the G10.1.G11.1 mutation, which eliminates the cleavage activity in the wild-type. The binding sites of the oligonucleotide were identified by photo-crosslinking experiments and were found to be the predicted sites in the loop. This is the first report of a design aimed at positively controlling the activity of ribozymes by employing a structural motif. This method can be applied to control the activities of other functional RNAs with hairpin loops.     

Cooperative dimerization of a stably folded protein directed by a flexible RNA in the assembly of the HIV Rev dimer–RRE stem II complex

The binding of the HIV‐1 Rev protein as an oligomer to a viral RNA element, the Rev‐response element (RRE), mediates nuclear export of genomic RNA. Assembly of the Rev–RRE ribonucleoprotein (RNP) complex is nucleated by the binding of the first Rev molecule to stem IIB of the RRE. This is followed by stepwise addition of a total of ~six Rev molecules along the RRE through a combination of RNA–protein and protein–protein interactions. RRE stem II, which forms a three‐way junction consisting of stems IIA, IIB and IIC, has been shown to bind to two Rev molecules in a cooperative manner, with the second Rev molecule binding to the junction region of stem II. The results of base substitutions at the stem II junction, and characterization of stem II junction variants selected from a randomized library showed that an “open” flexible structure is preferred for binding of the second Rev molecule, and that binding of the second Rev molecule to the junction region is not sequence‐specific. Alanine substitutions of a number of Rev amino acid residues implicated to be important for Rev folding in previous structural studies were found to result in a dramatic decrease in the binding of the second Rev molecule. These results support the model that proper folding of Rev is critical in ensuring that the flexible RRE is able to correctly position Rev molecules for specific RNP assembly, and suggests that targeting Rev folding may be effective in the inhibition of Rev function. Copyright © 2015 John Wiley & Sons, Ltd.