Contributions of individual nucleotides to tertiary binding of substrate by a Pneumocystis carinii group I intron

Pneumocystis carinii is a mammalian pathogen that infects and kills immunocompromised hosts such as cancer and AIDS patients. The LSU rRNA precursor of P. carinii contains a conserved group I intron that is an attractive drug target because humans do not contain group I introns. The oligonucleotide r(AUGACU), whose sequence mimics the 3'-end of the 5'-exon, binds to a ribozyme derived from the intron with a K(d) of 5.2 nM, which is 61000-fold tighter than expected from base-pairing alone [Testa, S. M., Haidaris, G. C., Gigliotti, F., and Turner, D. H. (1997) Biochemistry 36, 9379-9385]. Thus, oligonucleotide binding is enhanced by tertiary interactions. To localize interactions that give rise to this tertiary stability, binding to the ribozyme has been measured as a function of oligonucleotide length and sequence. The results indicate that 4.3 kcal/mol of tertiary stability is due to a G.U pair that forms at the intron's splice junction. Eliminating nucleotides at the 5'-end of r(AUGACU) does not affect intron binding more than expected from differences in base-pairing until r((___)ACU), which binds much more tightly than expected. Adding a C at the 5'- or 3'-end that can potentially form a C-G pair with the target has little effect on binding affinity. Truncated oligonucleotides were tested for their ability to inhibit intron self-splicing via a suicide inhibition mechanism. The tetramer, r((__)GACU), retains similar binding affinity and reactivity as the hexamer, r(AUGACU). Thus oligonucleotides as short as tetramers might serve as therapeutics that can use a suicide inhibition mechanism to inhibit self-splicing. Results with a phosphoramidate tetramer and thiophosphoramidate hexamer indicate that oligonucleotides with backbones stable to nuclease digestion retain favorable binding and reactivity properties.     

Molecular recognition properties of IGS-mediated reactions catalyzed by a Pneumocystis carinii group I intron

We report the development, analysis and use of a new combinatorial approach to analyze the substrate sequence dependence of the suicide inhibition, cyclization, and reverse cyclization reactions catalyzed by a group I intron from the opportunistic pathogen Pneumocystis carinii. We demonstrate that the sequence specificity of these Internal Guide Sequence (IGS)-mediated reactions is not high. In addition, the sequence specificity of suicide inhibition decreases with increasing MgCl₂ concentration, reverse cyclization is substantially more sequence specific than suicide inhibition, and multiple reverse cyclization products occur, in part due to the formation of multiple cyclization intermediates. Thermodynamic analysis reveals that a base pair at position –4 of the resultant 5′ exon–IGS (P1) helix is crucial for tertiary docking of the P1 helix into the catalytic core of the ribozyme in the suicide inhibition reaction. In contrast to results reported with a Tetrahymena ribozyme, altering the sequence of the IGS of the P.carinii ribozyme can result in a marked reduction in tertiary stability of docking the resultant P1 helix into the catalytic core of the ribozyme. Finally, results indicate that RNA targeting strategies which exploit tertiary interactions could have low specificity due to the tolerance of mismatched base pairs.     

Thermodynamic stability and structural features of the J4/5 loop in a Pneumocystis carinii group I intron

The J4/5 loop of the group I intron in the mouse-derived fungal pathogen Pneumocystis carinii is the docking site for the first step of the RNA-catalyzed self-splicing reaction and thus is a model of a potential drug target. This purine-rich asymmetric internal loop, 5'GGAAG/3'UAGU, is also thermodynamically more stable than other internal loops with two GU closing pairs and three nucleotides opposite two nucleotides. The results from optical melting, nuclear magnetic resonance spectroscopy, and functional group substitution experiments suggest that the GU closing pairs form and that sheared GA pairs form in the internal loop. The NMR spectra show evidence of conformational dynamics, and several GA pairings are possible. Thus, this dynamic loop presents several possible structures for potential binding of drugs that target group I self-splicing introns. The results also contribute to understanding the structural and dynamic basis for the function and thermodynamic stability of this loop.     

New approaches to targeting RNA with oligonucleotides: inhibition of group I intron self-splicing

RNA is one class of relatively unexplored drug targets. Since RNAs play a myriad of essential roles, it is likely that new drugs can be developed that target RNA. There are several factors that make targeting RNA particularly attractive. First, the amount of information about the roles of RNA in essential biological processes is currently being expanded. Second, sequence information about targetable RNA is pouring out of genome sequencing efforts at unprecedented levels. Third, designing and screening potential oligonucleotide therapeutics to target RNA is relatively simple. The use of oligonucleotides in cell culture, however, presents several challenges such as oligonucleotide uptake and stability, and selective targeting of genes of interest. Here, we review investigations aimed at targeting RNA with oligonucleotides that can circumvent several of these potential problems. The hallmark of the strategies discussed is the use of short oligonucleotides, which may have the advantage of higher cellular uptake and improved binding selectivity compared to longer oligonucleotides. These strategies have been applied to Group I introns from the mammalian pathogens Pneumocystis carinii and Candida albicans. Both are examples of fungal infections that are increasing in number and prevalence.     

Hydrolytic cleavage by a group I intron ribozyme is dependent on RNA structures not important for splicing.

DiGIR2 is the group I splicing-ribozyme of the mobile twin-ribozyme intron Dir.S956-1, present in Didymium nuclear ribosomal DNA. DiGIR2 is responsible for intron excision, exon ligation, 3'-splice site hydrolysis, and full-length intron RNA circle formation. We recently reported that DiGIR2 splicing (intron excision and exon ligation) competes with hydrolysis and subsequent full-length intron circularization. Here we present experimental evidence that hydrolysis at the 3'-splice site in DiGIR2 is dependent on structural elements within the P9 subdomain not involved in splicing. Whereas the GCGA tetra-loop in P9b was found to be important in hydrolytic cleavage, probably due to tertiary RNA-RNA interactions, the P9.2 hairpin structure was found to be essential for hydrolysis. The most important positions in P9.2 include three adenosines in the terminal loop (L9.2) and a consensus kink-turn motif in the proximal stem. We suggest that the L9.2 adenosines and the kink-motif represent key regulatory elements in the splicing and hydrolytic reaction pathways.     

Coordination of two sequential ester-transfer reactions: exogenous guanosine binding promotes the subsequent omegaG binding to a group I intron

Self-splicing of group I introns is accomplished by two sequential ester-transfer reactions mediated by sequential binding of two different guanosine ligands, but it is yet unclear how the binding is coordinated at a single G-binding site. Using a three-piece trans-splicing system derived from the Candida intron, we studied the effect of the prior GTP binding on the later ωG binding by assaying the ribozyme activity in the second reaction. We showed that adding GTP simultaneously with and prior to the esterified ωG in a substrate strongly accelerated the second reaction, suggesting that the early binding of GTP facilitates the subsequent binding of ωG. GTP-mediated facilitation requires C2 amino and C6 carbonyl groups on the Watson–Crick edge of the base but not the phosphate or sugar groups, suggesting that the base triple interactions between GTP and the binding site are important for the subsequent ωG binding. Strikingly, GTP binding loosens a few local structures of the ribozyme including that adjacent to the base triple, providing structural basis for a rapid exchange of ωG for bound GTP.     

Association of a group I intron with its splice junction in 50S ribosomes: implications for intron toxicity.

The effect of genetic context on splicing of group I introns is not well understood at present. The influence of ribosomal RNA conformation on splicing of rDNA introns in vivo was investigated using a heterologous system in which the Tetrahymena group I intron is inserted into the homologous position of the Escherichia coli 23S rRNA. Mutations that block splicing in E. coli result in accumulation of unspliced 23S rRNA that is assembled into 50S complexes, but not 70S ribosomes. The data indicate that accommodation of the intron structure on the surface of the 50S subunit inhibits interactions with the small ribosomal subunit. Spliced intron RNA also remains noncovalently bound to 50S subunits on sucrose gradients. This interaction appears to be mediated by base pairing between the intron guide sequence and the 23S rRNA, because the fraction of bound intron RNA is reduced by point mutations in the IGS or deletion of the P1 helix. Association of the intron with 50S subunits correlates with slow cell growth. The results suggest that group I introns have the potential to inhibit protein synthesis in prokaryotes by direct interactions with ribosomes.     

Thermodynamics of RNA-RNA duplexes with 2- or 4-thiouridines: implications for antisense design and targeting a group I intron

Antisense compounds are designed to optimize selective hybridization of an exogenous oligonucleotide to a cellular target. Typically, Watson-Crick base pairing between the antisense compound and target provides the key recognition element. Uridine (U), however, not only stably base pairs with adenosine (A) but also with guanosine (G), thus reducing specificity. Studies of duplex formation by oligonucleotides with either an internal or a terminal 2- or 4-thiouridine (s(2)U or s(4)U) show that s(2)U can increase the stability of base pairing with A more than with G, while s(4)U can increase the stability of base pairing with G more than with A. The latter may be useful when binding can be enhanced by tertiary interactions with a s(4)U-G pair. To test the effects of s(2)U and s(4)U substitutions on tertiary interactions, binding to a group I intron ribozyme from mouse-derived Pneumocystis carinii was measured for the hexamers, r(AUGACU), r(AUGACs(2)U), and r(AUGACs(4)U), which mimic the 3' end of the 5' exon. The results suggest that at least one of the carbonyl groups of the 3' terminal U of r(AUGACU) is involved in tertiary interactions with the catalytic core of the ribozyme and/or thio groups change the orientation of a terminal U-G base pair. Thus thio substitutions may affect tertiary interactions. Studies of trans-splicing of 5' exon mimics to a truncated rRNA precursor, however, indicate that thio substitutions have negligible effects on overall reactivity. Therefore, modified bases can enhance the specificity of base pairing while retaining other activities and, thus, increase the specificity of antisense compounds targeting cellular RNA.     

A protein required for splicing group I introns in Neurospora mitochondria is mitochondrial tyrosyl-tRNA synthetase or a derivative thereof

The nuclear cyt-18 mutants of Neurospora crassa are defective in splicing a number of group I introns in mitochondria. Here, cloning and sequencing of the cyt-18 gene show that it contains an open reading frame having significant homology to bacterial tyrosyl-tRNA synthetases. Biochemical and genetic experiments lead to the conclusions that the cyt-18 gene encodes mitochondrial tyrosyl-tRNA synthetase, that mutations in this gene inhibit splicing directly, and that mitochondrial tyrosyl-tRNA synthetase or a derivative of this protein is related to the soluble activity that functions in splicing the mitochondrial large rRNA intron and possibly other group I introns. Analysis of partial revertants provides direct evidence that the cyt-18 gene encodes a protein or proteins with two activities, splicing and aminoacylation, that can be partially separated by mutation. Our findings may be relevant to the evolution of introns and splicing mechanisms in eukaryotes.     

Interaction of intronic boundaries is required for the second splicing step efficiency of a group II intron.

Group II and nuclear pre-mRNAs introns share a common splicing pathway involving a lariat intermediate, as well as some primary sequence similarities at the splice junctions. In this work, we analyze the role of the conserved nucleotides at the first and penultimate positions (G1 and A886) of a group II self-splicing intron. We show that the G1 nucleotide is essential for the efficiency of both the first and the second splicing steps, while substitutions at the penultimate nucleotide affect mostly the efficiency of the second step. A reciprocal suppression of the second splicing step defect can be observed in some double mutants. This result is best explained by a non-Watson-Crick interaction between the first and the penultimate nucleotides of the intron, which occurs after lariat formation. The finding that an interaction between intron boundaries is required for the second splicing step in both group II and nuclear pre-mRNA introns strengthens the idea that both systems employ similar mechanisms, albeit with differences in the details of the nucleotide interactions.     

A shared RNA-binding site in the Pet54 protein is required for translational activation and group I intron splicing in yeast mitochondria

The Pet54p protein is an archetypical example of a dual functioning (‘moonlighting’) protein: it is required for translational activation of the COX3 mRNA and splicing of the aI5β group I intron in the COX1 pre-mRNA in Saccharomyces cerevisiae mitochondria (mt). Genetic and biochemical analyses in yeast are consistent with Pet54p forming a complex with other translational activators that, in an unknown way, associates with the 5′ untranslated leader (UTL) of COX3 mRNA. Likewise, genetic analysis suggests that Pet54p along with another distinct set of proteins facilitate splicing of the aI5β intron, but the function of Pet54 is, also, obscure. In particular, it remains unknown whether Pet54p is a primary RNA-binding protein that specifically recognizes the 5′ UTL and intron RNAs or whether its functional specificity is governed in other ways. Using recombinant protein, we show that Pet54p binds with high specificity and affinity to the aI5β intron and facilitates exon ligation in vitro. In addition, Pet54p binds with similar affinity to the COX3 5′ UTL RNA. Competition experiments show that the COX3 5′UTL and aI5β intron RNAs bind to the same or overlapping surface on Pet54p. Delineation of the Pet54p-binding sites by RNA deletions and RNase footprinting show that Pet54p binds across a similar length sequence in both RNAs. Alignment of the sequences shows significant (56%) similarity and overlap between the binding sites. Given that its role in splicing is likely an acquired function, these data support a model in which Pet54p's splicing function may have resulted from a fortuitous association with the aI5β intron. This association may have lead to the selection of Pet54p variants that increased the efficiency of aI5β splicing and provided a possible means to coregulate COX1 and COX3 expression.     

Functionally distinct nucleic acid binding sites for a group I intron encoded RNA maturase/DNA homing endonuclease

A large number of group I introns encode a family of homologous proteins that either promote intron splicing (maturases) or are site-specific DNA endonucleases that function in intron mobility (a process called "homing"). Genetic studies have shown that some of these proteins have both activities, yet how a single protein carries out both functions remains obscure. The similarity between respective DNA-binding sites and the RNA structure near the 5' and 3' splice sites has fueled speculation that such proteins may use analogous interactions to perform both functions. The Aspergillus nidulans mitochondrial COB group I intron encodes a bi-functional protein, I-AniI, that has both RNA maturase and site-specific DNA endonuclease activities in vitro. Here, we show that I-AniI shows distinctive features of the endonuclease family to which it belongs, including highly specific, tight binding and sequential DNA strand cleavage. Competition experiments demonstrate that I-AniI binds the COB intron RNA even in saturating concentrations of its DNA target site substrate, suggesting that the protein has a separate binding site for RNA. In addition, we provide evidence that two different DNA-binding site mutants of I-AniI have little effect on the protein's RNA maturation activity. Since RNA splicing is likely a secondary adaptation of the protein, these observations support a model in which homing endonucleases may have developed maturase function by utilizing a hitherto "non-functional" protein surface.     

Structure-function relationships in a self-splicing group II intron: a large part of domain II of the mitochondrial intron aI5 is not essential for self-splicing.

An oligonucleotide-directed deletion of 156 nucleotides has been introduced into the yeast mitochondrial group II intron al5 (887 nt). The deletion comprises almost all of domain II, which is one of the six phylogenetically conserved structural elements of group II introns. This mutant displays reduced self-splicing activity, but results of chemical probing with dimethylsulphate suggest that sequences at the site of the deletion interfere with the normal folding of the intron. This is supported by computer analyses, which predict a number of alternative structures involving conserved intron sequences. Splicing activity could be restored by insertion of a 10-nucleotide palindromic sequence into the unique Smal site of the deletion mutant, resulting in the formation of a small stable stem-loop element at the position of domain II. These results provide a direct correlation between folding of the RNA and its activity. We conclude that at least a large part of domain II of the group II intron al5 is not required for self-splicing activity. This deletion mutant with a length of 731 nucleotides represents the smallest self-splicing group II intron so far known.     

Structural metals in the group I intron: a ribozyme with a multiple metal ion core

Metal ions play key roles in the folding and function for many structured RNAs, including group I introns. We determined the X-ray crystal structure of the Azoarcus bacterial group I intron in complex with its 5' and 3' exons. In addition to 222 nucleotides of RNA, the model includes 18 Mg(2+) and K(+) ions. Five of the metals bind within 12 A of the scissile phosphate and coordinate the majority of the oxygen atoms biochemically implicated in conserved metal-RNA interactions. The metals are buried deep within the structure and form a multiple metal ion core that is critical to group I intron structure and function. Eight metal ions bind in other conserved regions of the intron structure, and the remaining five interact with peripheral structural elements. Each of the 18 metals mediates tertiary interactions, facilitates local bends in the sugar-phosphate backbone or binds in the major groove of helices. The group I intron has a rich history of biochemical efforts aimed to identify RNA-metal ion interactions. The structural data are correlated to the biochemical results to further understand the role of metal ions in group I intron structure and function.     

The conserved U.G pair in the 5'' splice site duplex of a group I intron is required in the first but not the second step of self-splicing.

Group I self-splicing introns have a 5' splice site duplex (P1) that contains a single conserved base pair (U.G). The U is the last nucleotide of the 5' exon, and the G is part of the internal guide sequence within the intron. Using site-specific mutagenesis and analysis of the rate and accuracy of splicing of the Tetrahymena thermophila group I intron, we found that both the U and the G of the U.G pair are important for the first step of self-splicing (attack of GTP at the 5' splice site). Mutation of the U to a purine activated cryptic 5' splice sites in which a U.G pair was restored; this result emphasizes the preference for a U.G at the splice site. Nevertheless, some splicing persisted at the normal site after introduction of a purine, suggesting that position within the P1 helix is another determinant of 5' splice site choice. When the U was changed to a C, the accuracy of splicing was not affected, but the Km for GTP was increased by a factor of 15 and the catalytic rate constant was decreased by a factor of 7. Substitution of U.A, U.U, G.G, or A.G for the conserved U.G decreased the rate of splicing by an even greater amount. In contrast, mutation of the conserved G enhanced the second step of splicing, as evidenced by a trans-splicing assay. Furthermore, a free 5' exon ending in A or C instead of the conserved U underwent efficient ligation. Thus, unlike the remainder of the P1 helix, which functions in both the first and second steps of self-splicing, the conserved U.G appears to be important only for the first step.     

Sperm mitochondrial integrity is not required for hyperactivated motility, zona binding, or acrosome reaction in the rhesus macaque

Whether the main energy source for sperm motility is from oxidative phosphorylation or glycolysis has been long-debated in the field of reproductive biology. Using the rhesus monkey as a model, we examined the role of glycolysis and oxidative phosphorylation in sperm function by using alpha-chlorohydrin (ACH), a glycolysis inhibitor, and pentachlorophenol (PCP), an oxidative phosphorylation uncoupler. Sperm treated with ACH showed no change in percentage of motile sperm, although sperm motion was impaired. The ACH-treated sperm did not display either hyperactivity- or hyperactivation-associated changes in protein tyrosine phosphorylation. When treated with PCP, sperm motion parameters were affected by the highest level of PCP (200 microM); however, PCP did not cause motility impairments even after chemical activation. Sperm treated with PCP were able to display hyperactivity and tyrosine phosphorylation after chemical activation. In contrast with motility measurements, treatment with either the glycolytic inhibitor or the oxidative phosphorylation inhibitor did not affect sperm-zona binding and zona-induced acrosome reaction. The results suggest glycolysis is essential to support sperm motility, hyperactivity, and protein tyrosine phosphorylation, while energy from oxidative phosphorylation is not necessary for hyperactivated sperm motility, tyrosine phosphorylation, sperm-zona binding, and acrosome reaction in the rhesus macaque.