Specific arginine mediated RNA recognition

In many biological systems substantial roles are played by interactions between amino acids and RNA. Among amino acids L-arginine seems to be particularly relevant, because the guanidinium group of arginine side chain can potentially form five hydrogen bonds with appropriately positioned acceptor groups of RNA. Extensive studies reveal that specific arginine recognition is achieved by many different RNAs over a broad range of binding affinities. Arginine is frequently found among amino acids in the nucleic acid-binding motifs in various proteins. For example, specific binding of the HIV-1 Tat protein to its RNA site (TAR) is mediated by a single arginine residue. Free arginine can be also bound by the guanosine site in the group I Tetrahymena ribosomal RNA intron catalytic centre, as well as by numerous RNA motifs, called arginine aptamers, which have been selected in vitro.     

Specificity of arginine binding by the Tetrahymena intron

L-Arginine competitively inhibits the reaction of GTP with the Tetrahymena ribosomal self-splicing intron. In order to define this RNA binding site for arginine, Ki's have now been measured for numerous arginine-like competitive inhibitors. Detailed consideration of the Ki's suggests a tripartite binding model. The dissociation constants of the inhibitors can be consistently interpreted if the guanidino group of arginine binds in the GTP site by utilizing the H-bonds otherwise made to the N1-H and 2 NH2 of the guanine pyrimidine ring. The positive charge of the arginine guanidino group also enhances binding. A second requirement is for the precise length of the aliphatic arm connecting the guanidino with the alpha-carbon. The positive charge of the alpha-amino group is the third feature essential to effective inhibition. The negative carboxyl charge of arginine inhibits binding, and the substituents on the alpha-carbon are probably oriented, with the alpha-amino group near the phosphate backbone of the RNA. This orientation contributes strongly to the L stereoselectivity of the amino acid site on the RNA. When spaced optimally, net contribution to the free energy of binding is of the same order for the guanidino group and for the arginine alpha-carbon substituents, but the guanidino apparently contributes more to binding free energy. Taken together, these observations extend the previous binding model [Yarus, M. (1988) Science (Washington, D.C.) 240, 1751-1758]. The observed dependence of binding on universal characteristics of amino acids suggests that RNA binding sites with other amino acid specificities could exist.     

Selection of small molecules by the Tetrahymena catalytic center.

The catalytic center in group I RNAs contains a selective binding site that accommodates both guanosine and L-arginine. In order to understand the specificity of the RNA for small molecules, we analyzed 6 RNAs that vary in this region. Specificity for nucleotides resides substantially in G264 rather than its paired nucleotide C311, and is expressed substantially in Km, with comparatively little variation in kcat. kcat is not notably perturbed even for RNAs with mispairs in the active-site helix. For 5 of 6 sequences, effects of RNA substitutions on arginine binding and GTP reactivity are proportional, confirming that arginine contacts a subset of the groups occupied by G. As a result of particular mutations, reaction with GTP is decreased, and reaction with the natural nucleotides UTP and ATP is enhanced. Molecular modeling of these effects suggests that exceptionally flexible placement of reactants may be an essential quality of RNA-catalyzed splicing. The specificity of the intron can be rationalized by a type of binding model not previously considered, in which the G/arginine site includes adjacent nucleotides (an 'axial' site), rather than a single nucleotide, G264.     

An RNA-amino acid complex and the origin of the genetic code

The group I RNAs, of which the Tetrahymena ribosomal RNA intron is the most investigated example, catalyze their own splicing reactions. Splicing is initiated at a conserved site on the RNA that facilitates attack by exogenous guanosine (or its nucleotides) on the exon-intron junction. The guanosine site in the RNA's catalytic center also binds arginine, and is quite selective for the arginine side chain. This amino acid-RNA interaction is stereoselective, and L-arginine is preferred. Immediately at the site at which arginine binds there is one of only four RNA triplets in 92 group I RNA sequences: AGA/G and CGA/G. Thus the arginine contact site is within any of four different codons for arginine. Mutation of the conserved G in the middle of the triplet decreases affinity for the amino acid, showing that binding is sequence-specific. A pathway for the origin of the genetic code for arginine is suggested, based on the existence and properties of this sequence-specific, amino acid-specific RNA complex. The existence of a proto-ribosome related to the group I RNAs seems the most likely hypothesis. This notion is used to distinguish three periods in the development of the code. Restrained and exuberant hypotheses about the origin of the genetic code are distinguished, and some objections to these hypotheses are considered.     

Novel splicing mechanism for the ribosomal RNA intron in the archaebacterium Desulfurococcus mobilis

The intron of the 23S rRNA gene of D. mobilis is excised from the pre-23S RNA at specific sites in vivo and subsequently ligated to form a stable circular RNA, with a normal 5'-3' phosphodiester bond, containing the entire intron sequence; 95% of this RNA codes for a protein of 194 amino acids that can be expressed in E. coli. Crude cell extracts from D. mobilis also induce a two-step slicing reaction in vitro, producing the same circular intron RNA but a low yield of ligated exons. Cleavage depends on the RNA structure adjacent to the cleavage site and yields a 3'-terminal phosphate. Splicing is enhanced by GTP, but does not require divalent metal ions. The cleavage and exon-splicing reactions resemble those found for tRNA introns in eukaryotes and a possible structural rationale for this similarity is considered together with its possible implications for the origin of eukaryotic rRNA and tRNA introns.     

CRS1, a chloroplast group II intron splicing factor, promotes intron folding through specific interactions with two intron domains

Group II introns are ribozymes that catalyze a splicing reaction with the same chemical steps as spliceosome-mediated splicing. Many group II introns have lost the capacity to self-splice while acquiring compensatory interactions with host-derived protein cofactors. Degenerate group II introns are particularly abundant in the organellar genomes of plants, where their requirement for nuclear-encoded splicing factors provides a means for the integration of nuclear and organellar functions. We present a biochemical analysis of the interactions between a nuclear-encoded group II splicing factor and its chloroplast intron target. The maize (Zea mays) protein Chloroplast RNA Splicing 1 (CRS1) is required specifically for the splicing of the group II intron in the chloroplast atpF gene and belongs to a plant-specific protein family defined by a recently recognized RNA binding domain, the CRM domain. We show that CRS1's specificity for the atpF intron in vivo can be explained by CRS1's intrinsic RNA binding properties. CRS1 binds in vitro with high affinity and specificity to atpF intron RNA and does so through the recognition of elements in intron domains I and IV. These binding sites are not conserved in other group II introns, accounting for CRS1's intron specificity. In the absence of CRS1, the atpF intron has little uniform tertiary structure even at elevated [Mg2+]. CRS1 binding reorganizes the RNA, such that intron elements expected to be at the catalytic core become less accessible to solvent. We conclude that CRS1 promotes the folding of its group II intron target through tight and specific interactions with two peripheral intron segments.     

Distinct sites of phosphorothioate substitution interfere with folding and splicing of the Anabaena group I intron

Although the active site of group I introns is phylogenetically conserved, subclasses of introns have evolved different mechanisms of stabilizing the catalytic core. Large introns contain weakly conserved 'peripheral' domains that buttress the core through predicted interhelical contacts, while smaller introns use loop-helix interactions for stability. In all cases, specific and non-specific magnesium ion binding accompanies folding into the active structure. Whether similar RNA-RNA and RNA-magnesium ion contacts play related functional roles in different introns is not clear, particularly since it can be difficult to distinguish interactions directly involved in catalysis from those important for RNA folding. Using phosphorothioate interference with RNA activity and structure in the small (249 nt) group I intron from Anabaena, we used two independent assays to detect backbone phosphates important for catalysis and those involved in intron folding. Comparison of the interference sites identified in each assay shows that positions affecting catalysis cluster primarily in the conserved core of the intron, consistent with conservation of functionally important phosphates, many of which are magnesium ion binding sites, in diverse group I introns, including those from Azoarcus and Tetrahymena. However, unique sites of folding interference located outside the catalytic core imply that different group I introns, even within the same subclass, use distinct sets of tertiary interactions to stabilize the structure of the catalytic core.     

Characterization of the self-splicing products of two complex Naegleria LSU rDNA group I introns containing homing endonuclease genes.

The two group I introns Nae.L1926 and Nmo.L2563, found at two different sites in nuclear LSU rRNA genes of Naegleria amoebo-flagellates, have been characterized in vitro. Their structural organization is related to that of the mobile Physarum intron Ppo.L1925 (PpLSU3) with ORFs extending the L1-loop of a typical group IC1 ribozyme. Nae.L1926, Nmo.L2563 and Ppo.L1925 RNAs all self-splice in vitro, generating ligated exons and full-length intron circles as well as internal processed excised intron RNAs. Formation of full-length intron circles is found to be a general feature in RNA processing of ORF-containing nuclear group I introns. Both Naegleria LSU rDNA introns contain a conserved polyadenylation signal at exactly the same position in the 3' end of the ORFs close to the internal processing sites, indicating an RNA polymerase II-like expression pathway of intron proteins in vivo. The intron proteins I-NaeI and I-NmoI encoded by Nae.L1926 and Nmo.L2563, respectively, correspond to His-Cys homing endonucleases of 148 and 175 amino acids. I-NaeI contains an additional sequence motif homologous to the unusual DNA binding motif of three antiparallel beta sheets found in the I-PpoI endonuclease, the product of the Ppo.L1925 intron ORF.     

Transposition of two amino acids changes a promiscuous RNA binding protein into a sequence-specific RNA binding protein

In yeast (Saccharomyces cerevisiae), the branchpoint binding protein (BBP) recognizes the conserved yeast branchpoint sequence (UACUAAC) with a high level of specificity and affinity, while the human branchpoint binding protein (SF1) binds the less-conserved consensus branchpoint sequence (CURAY) in human introns with a lower level of specificity and affinity. To determine which amino acids in BBP provide the additional specificity and affinity absent in SF1, a panel of chimeric SF1 proteins was tested in RNA binding assays with wild-type and mutant RNA substrates. This approach revealed that the QUA2 domain of BBP is responsible for the enhanced RNA binding affinity and specificity displayed by BBP compared with SF1. Within the QUA2 domain, a transposition of adjacent arginine and lysine residues is primarily responsible for the switch in RNA binding between BBP and SF1. Alignment of multiple branchpoint binding proteins and the related STAR/GSG proteins suggests that the identity of these two amino acids and the RNA target sequences of all of these proteins are correlated.     

Two group I introns with long internal open reading frames in the chloroplast psbA gene of Chlamydomonas moewusii.

We report the nucleotide sequence of the chloroplast psbA gene encoding the 32 kilodalton protein of photosystem II from Chlamydomonas moewusii. Like its land plant homologues, this green algal protein consists of 353 amino acids. The C. moewusii psbA gene is composed of three exons containing 252, 11 and 90 codons and of two group I introns containing 2363 and 1807 nucleotides. Each of the introns features an internal open reading frame (ORF) that potentially encodes a basic protein of more than 300 residues. The primary sequences of the putative intron-encoded proteins are unrelated and none of them shares conserved elements with any of the proteins predicted from the group I intron sequences published so far. The first C. moewusii intron is inserted at the same position as the fourth intron of the psbA gene from Chlamydomonas reinhardtii; the second intron lies at a novel site downstream of this position. On the basis of their RNA secondary structures, the C. moewusii introns 1 and 2 can be assigned to subgroups IA and IB, respectively. However, intron 1 is not typical of subgroup IA introns, its most unusual feature being the location of the ORF in the "loop L5" region. To our knowledge, this is the first time that an ORF is located in this region of the group I intron structure.     

Characterization of a specific transport system for arginine in isolated yeast vacuoles.

The transport of L-arginine was studied in isolated vacuoles of Saccharomyces cerevisiae. A centrifugation method allowed rapid separation of the fragile vacuoles from the incubation media so that initial uptake rates of [14C]arginine could be measured. Labelled arginine added to the medium was accumulated in the isolated vacuoles; it was found to exchange specifically with the arginine already present in the vacuoles. Such an exchange did not take place in intact spheroplasts. The pH dependence of the arginine transport in the vacuoles was tested. As the vacuoles are unstable in the pH range of optimal transport activity (pH above 7.0), the pH optimum of the transport reaction could not be determined. From the temperature dependence, the apparent energy of activation was calculated to be 9800 cal/mol. Arginine transport shows saturation kinetics with an apparent Km of 30 muM in the isolated vacuoles, and of 1.5 muM in the spheroplasts. Competition experiments with amino acids and arginine analogues demonstrated that the arginine transport in both vacuoles and spheroplasts, is highly specific. The two systems, however, were shown to have distinct specificities. The inhibition of vacuolar L-arginine transport by D-arginine, L-histidine, and L-canavanine was competitive with apparent Ki values of 60 muM, 400 muM and 600 muM respectively.     

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.     

Bidirectional effectors of a group I intron ribozyme.

The group I self-splicing introns found in many organisms are competitively inhibited by L-arginine. We have found that L-arginine acts stereoselectively on the Pc1. LSU nuclear group I intron of Pneumocystis carinii, competitively inhibiting the first (cleavage) step of the splicing reaction and stimulating the second (ligation) step. Stimulation of the second step is most clearly demonstrated in reactions whose first step is blocked after 15 min by addition of pentamidine. The guanidine moiety of arginine is required for both effects. L-Canavanine is a more potent inhibitor than L-arginine yet it fails to stimulate. L-Arginine derivatized on its carboxyl group as an amide, ester or peptide is more potent than L-arginine as a stimulator and inhibitor, with di-arginine amide and tri-arginine being the most potent effectors tested. The most potent peptides tested are 10,000 times as effective as L-arginine in inhibiting ribozyme activity, and nearly 400 times as effective as stimulators. Arginine and some of its derivatives apparently bind to site(s) on the ribozyme to alter its conformation to one more active in the second step of splicing while competing with guanosine substrate in the first step. This phenomenon indicates that ribozymes, like protein enzymes, can be inhibited or stimulated by non-substrate low molecular weight compounds, which suggests that such compounds may be developed as pharmacological agents acting on RNA targets.     

Naegleria nucleolar introns contain two group I ribozymes with different functions in RNA splicing and processing.

We have characterized the structural organization and catalytic properties of the large nucleolar group I introns (NaSSU1) of the different Naegleria species N. jamiesoni, N. andersoni, N. italica, and N. gruberi. NaSSU1 consists of three distinct RNA domains: an open reading frame encoding a homing-type endonuclease, and a small group I ribozyme (NaGIR1) inserted into the P6 loop of a second group I ribozyme (NaGIR2). The two ribozymes have different functions in RNA splicing and processing. NaGIR1 is an unusual self-cleaving group I ribozyme responsible for intron processing at two internal sites (IPS1 and IPS2), both close to the 5' end of the open reading frame. This processing is hypothesized to lead to formation of a messenger RNA for the endonuclease. Structurally, NaGIR2 is a typical group IC1 ribozyme, catalyzing intron excision and exon ligation reactions. NaGIR2 is responsible for circularization of the excised intron, a reaction that generates full-length RNA circles of wild-type intron. Although it is only distantly related in primary sequence, NaSSU1 RNA has a predicted organization and function very similar to that of the mobile group I intron DiSSU1 of Didymium, the only other group I intron known to encode two ribozymes. We propose that these twin-ribozyme introns define a distinct category of group I introns with a conserved structural organization and function.     

Cloning of a cDNA encoding porcine brain natriuretic peptide

Complimentary DNA (cDNA) clones encoding porcine brain natriuretic peptide (BNP) were isolated from a porcine atrial cDNA library. The longest of the cDNA clones (1507 nucleotides) apparently originated from an unprocessed messenger RNA, since the nucleotide sequence encoding BNP-26 was interrupted by an intron of 554 nucleotides. A partial cDNA clone representing processed BNP mRNA was prepared by polymerase chain reaction. A comparison of the sequence of these two cDNAs reveals the presence of an additional intron within the sequence encoding the BNP precursor. The identification of these introns suggests that the BNP gene structure differs from the atrial natriuretic peptide gene in the location of intron 2. BNP mRNA encodes a propeptide of 131 amino acids, including a signal peptide domain (25 amino acids) and a prohormone domain (106 amino acids). Like atrial natriuretic peptide, the bioactive BNP sequence is localized at the carboxyl terminus of the prohormone. Although the carboxyl-terminal peptide sequences of porcine atrial natriuretic peptide and BNP are well conserved, there is relatively little homology within their propeptide regions.     

Arginine decarboxylase from a Pseudomonas species.

An arginine decarboxylase has been isolated from a Pseudomonas species. The enzyme is constitutive and did not appear to be repressed by a variety of carbon sources. After an approximately 40-fold purification, the enzyme appeared more similar in its properties to the Escherichia coli biosynthetic arginine decarboxylase than to the E. coli inducible (biodegradative) enzyme. The Pseudomonas arginine decarboxylase exhibited a pH optimum of 8.1 and an absolute requirement of Mg2+ and pyridoxal phosphate, and was inhibited significantly at lower Mg2+ concentrations by the polyamines putrescine, spermidine, and cadaverine. The Km for L-arginine was about 0.25 mM at pH 8.1 AND 7.2. The enzyme was completely inhibited by p-chloromercuribenzoate. The inhibition was prevented by dithiothreitol, a feature that suggests the involvement of an -SH group. Of a variety of labeled amino acids tested, only L-arginine, but not D-arginine was decarboxylated. D-Arginine was a potent inhibitor of arginine decarboxylase with a Ki of 3.2 muM.     

Activity of chimeric RNAs of U6 snRNA and (-)sTRSV in the cleavage of a substrate RNA.

U6 small nuclear RNA is one of the spliceosomal RNAs essential for pre-mRNA splicing. Discovery of mRNA-type introns in the highly conserved region of the U6 snRNA genes led to the hypothesis that U6 snRNA functions as a catalytic element during pre-mRNA splicing. The highly conserved region of U6 snRNA has a structural similarity with the catalytic domain of the negative strand of the satellite RNA of tobacco ring spot virus [(-)sTRSV], suggesting that the highly conserved region of U6 snRNA forms the catalytic center. We examined whether synthetic RNAs consisting of the sequence of the highly conserved region of U6 snRNA or various chimeric RNAs between the U6 region and the catalytic RNA of (-)sTRSV could cleave a substrate RNA that can partially base-pair with them and have a GU sequence. Chimeric RNAs with 70 to 83% sequence identity with the conserved region of S. pombe U6 snRNA cleaved the substrate RNA at the 5' side of the GU sequence, which is shared by the 5' end of an intron in a pre-mRNA. We found that the highly conserved region of U6 snRNA and the catalytic domain of (-)sTRSV are strikingly similar in structure to the catalytic core region of the group I self-splicing intron in cyanobacteria. These results suggest that U6 snRNA, (-)sTRSV and the group I self-splicing intron originated from a common ancestral RNA, and support the hypothesis that U6 snRNA catalyzes pre-mRNA splicing reaction.     

Do introns favor or avoid regions of amino acid conservation?

Are intron positions correlated with regions of high amino acid conservation? For a set of ancient conserved proteins, with intronless prokaryotic but intron-containing eukaryotic homologs, multiple sequence alignments identified residues invariant throughout evolution. Intron positions between codons show no preferences. However, introns lying after the first base of a codon prefer conserved regions, markedly in glycines. Because glycines are in excess in conserved regions, this behavior could reflect phase-one introns entering glycine residues randomly in the ancestral sequences. Examination of intron positions within codons of evolutionarily invariable amino acids showed that roughly 50% of these introns are bordered by guanines at both 5'- and 3'-ends, 25% have a G only before the intron, and 5% have a G only after the intron, whereas about 20% are bordered by nonguanine bases.