Rapid RNA sequencing: nucleases from Staphylococcus aureus and Neurospora crassa discriminate between uridine and cytidine

Extracellular G-quadruplexes and Z-DNA protect biofilms from DNase I, and G-quadruplexes form a DNAzyme with peroxidase activity

Many bacteria form biofilms to protect themselves from predators or stressful environmental conditions. In the biofilm, bacteria are embedded in a protective extracellular matrix composed of polysaccharides, proteins and extracellular DNA (eDNA). eDNA most often is released from lysed bacteria or host mammalian cells, and it is the only matrix component most biofilms appear to have in common. However, little is known about the form DNA takes in the extracellular space, and how different non-canonical DNA structures such as Z-DNA or G-quadruplexes might contribute to its function in the biofilm. The aim of this study was to determine if non-canonical DNA structures form in eDNA-rich staphylococcal biofilms, and if these structures protect the biofilm from degradation by nucleases. We grew Staphylococcus epidermidis biofilms in laboratory media supplemented with hemin and NaCl to stabilize secondary DNA structures and visualized their location by immunolabelling and fluorescence microscopy. We furthermore visualized the macroscopic biofilm structure by optical coherence tomography. We developed assays to quantify degradation of Z-DNA and G-quadruplex DNA oligos by different nucleases, and subsequently investigated how these enzymes affected eDNA in the biofilms. Z-DNA and G-quadruplex DNA were abundant in the biofilm matrix, and were often present in a web-like structures. In vitro, the structures did not form in the absence of NaCl or mechanical shaking during biofilm growth, or in bacterial strains deficient in eDNA or exopolysaccharide production. We thus infer that eDNA and polysaccharides interact, leading to non-canonical DNA structures under mechanical stress when stabilized by salt. We also confirmed that G-quadruplex DNA and Z-DNA was present in biofilms from infected implants in a murine implant-associated osteomyelitis model. Mammalian DNase I lacked activity against Z-DNA and G-quadruplex DNA, while Micrococcal nuclease could degrade G-quadruplex DNA and S1 Aspergillus nuclease could degrade Z-DNA. Micrococcal nuclease, which originates from Staphylococcus aureus, may thus be key for dispersal of biofilm in staphylococci. In addition to its structural role, we show for the first time that the eDNA in biofilms forms a DNAzyme with peroxidase-like activity in the presence of hemin. While peroxidases are part of host defenses against pathogens, we now show that biofilms can possess intrinsic peroxidase activity in the extracellular matrix.

HITS-CLIP: panoramic views of protein-RNA regulation in living cells

The study of gene regulation in cells has recently begun to shift from a period dominated by the study of transcription factor-DNA interactions to a new focus on RNA regulation. This was sparked by the still-emerging recognition of the central role for RNA in cellular complexity emanating from the RNA World hypothesis, and has been facilitated by technologic advances, in particular high throughput RNA sequencing and crosslinking methods (RNA-Seq, CLIP, and HITS-CLIP). This study will place these advances in context, and, focusing on CLIP, will explain the method, what it can be used for, and how to approach using it. Examples of the successes, limitations, and future of the technique will be discussed.

Production and purification of staphylococcal nuclease in Lactococcus lactis using a new expression-secretion system and a pH-regulated mini-reactor

BACKGROUND

Staphylococcal (or micrococcal) nuclease or thermonuclease (SNase or Nuc) is a naturally-secreted nucleic acid degrading enzyme that participates in Staphylococcus aureus spread in the infected host. Purified Nuc protein can be used as an exogenous reagent to clear cellular extracts and improve protein purification. Here, a recombinant form of Nuc was produced and secreted in a Gram-positive host, Lactococcus lactis, and purified from the culture medium.

RESULTS

The gene segment corresponding to the S. aureus nuclease without its signal peptide was cloned in an expression-secretion vector. It was then fused to a lactococcal sequence encoding a signal peptide, and expressed under the control of a lactococcal promoter that is inducible by zinc starvation. An L. lactis subsp cremoris model strain (MG1363) transformed with the resulting plasmid was grown in either of two media (GM17v and CDM) that are free of animal compounds, allowing GMP (Good Manufacturing Practice) production. Induction conditions (concentration of the metal chelator EDTA and timing of addition) in small-scale pH-regulated fermentors were optimized using LacMF (Lactis Multi-Fermentor), a home-made parallel fermentation control system able to monitor 12 reactors simultaneously. Large amounts of recombinant Nuc (rNuc) were produced and secreted in both media, and rNuc was purified from GM17v medium in a single-step procedure.

CONCLUSIONS

In L. lactis, rNuc production and secretion were optimal after induction by 0.5 mM EDTA in small scale (200 mL) GM17v exponential phase cultures (at an OD(600) of 2), leading to a maximal protein yield of 210 mg per L of culture medium. Purified rNuc was highly active, displaying a specific activity of 2000 U/mg.

Identification of RNA molecules by specific enzyme digestion and mass spectrometry: software for and implementation of RNA mass mapping

The idea of identifying or characterizing an RNA molecule based on a mass spectrum of specifically generated RNA fragments has been used in various forms for well over a decade. We have developed software—named RRM for ‘RNA mass mapping’—which can search whole prokaryotic genomes or RNA FASTA sequence databases to identify the origin of a given RNA based on a mass spectrum of RNA fragments. As input, the program uses the masses of specific RNase cleavage of the RNA under investigation. RNase T1 digestion is used here as a demonstration of the usability of the method for RNA identification. The concept for identification is that the masses of the digestion products constitute a specific fingerprint, which characterize the given RNA. The search algorithm is based on the same principles as those used in peptide mass fingerprinting, but has here been extended to work for both RNA sequence databases and for genome searches. A simple and powerful probability model for ranking RNA matches is proposed. We demonstrate viability of the entire setup by identifying the DNA template of a series of RNAs of biological and of in vitro transcriptional origin in complete microbial genomes and by identifying authentic 16S ribosomal RNAs in a ‘small ribosomal subunit RNA’ database. Thus, we present a new tool for a rapid identification of unknown RNAs using only a few picomoles of starting material.

The nature and biological significance of linear potato spindle tuber viroid molecules

"Naturally occurring" linear potato spindle tuber viroid (PSTVL) was shown to be as infectious as circular PSTV (PSTVc). The occurrence of PSTVL was shown not to be (a) an artifact of the extraction procedure per se; (b) due to the presence of metal ions in extraction buffers; or (c) related to the host species used for propagation, to a particular PSTV strain, or to the duration of infection. From labeling and blot-hybridization experiments, it was concluded that in infected tissue PSTVc appears first followed by PSTVL, which is produced as the result of cleavage of PSTVc at specific sites. One of the sites of cleavage of PSTVc was delineated by 5'-end labeling PSTVL, digesting it with RNase T1, separating the fragments by two-dimensional gel electrophoresis, and sequencing the major RNase T1-resistant fragments. The major site of in vitro labeling was shown to be variable, but was confined to the right-hand loop of PSTVc, i.e., between nucleotides 177 and 182. Furthermore, the right-hand end stem and loop of PSTVc contains sequences which are similar to a rDNA gene promoter sequence, and thus we suggest that DNA-dependent RNA polymerase I may be involved in viroid biosynthesis. Other cleavage sites in PSTV were determined by primer extension cDNA synthesis and by dideoxynucleotide chain termination, and were shown to correspond to nucleotides 113-114 and 80-81 and to sequences in the region of 334-340, 300-312, and 271-275. The significance of these cleavage sites is discussed.

Cucumber mosaic virus-associated RNA 5: X. The complete nucleotide sequence of a CARNA 5 incapable of inducing tomato necrosis

The complete nucleotide sequence of a cucumber mosaic virus-associated RNA 5 (CARNA 5) that does not induce the tomato necrosis disease (J. M. Kaper, M. E. Tousignant, and S. M. Thompson, Virology 114, 526-533, 1981) has been determined and compared with the known sequence of a necrosis-inducing CARNA 5 (K. E. Richards, G. Jonard, M. Jacquemond, and H. Lot, Virology 89, 395-408, 1978). The nonnecrotic satellite RNA, (1)CARNA 5, is one nucleotide smaller yet 93% homologous with (n)CARNA 5, the necrosis-inducing satellite RNA. (1)CARNA 5 differs from (n)CARNA 5 by 21 substitutions, 3 deletions, and 2 insertions, with more changes in the 3' half than in the 5' half of the molecule. (1)CARNA 5, like (n)CARNA 5, is capped at its 5' terminus; the nucleotide sequences predict that putative translational products of the two RNAs could be significantly different.

Sequence of the 3' untranslated region of brome mosaic virus coat protein messenger RNA

The 3' terminal 337 bases of BMV (brome mosaic virus) coat protein mRNA (BMV RNA4) are presented. This sequence includes the terminal portion of the coat protein cistron and the complete 300-base 3' noncoding sequence. The 3' noncoding sequence displays significant complementarity to the 5' terminal sequence of BMV RNA3 but not to the 5' terminal sequence of BMV RNA4.

The nuclease a-inhibitor complex is characterized by a novel metal ion bridge

Nonspecific, extracellular nucleases have received enhanced attention recently as a consequence of the critical role that these enzymes can play in infectivity by overcoming the host neutrophil defense system. The activity of the cyanobacterial nuclease NucA, a member of the betabetaalpha Me superfamily, is controlled by the specific nuclease inhibitor, NuiA. Here we report the 2.3-A resolution crystal structure of the NucA-NuiA complex, showing that NucA inhibition by NuiA involves an unusual divalent metal ion bridge that connects the nuclease with its inhibitor. The C-terminal Thr-135(NuiA) hydroxyl oxygen is directly coordinated with the catalytic Mg(2+) of the nuclease active site, and Glu-24(NuiA) also extends into the active site, mimicking the charge of a scissile phosphate. NuiA residues Asp-75 and Trp-76 form a second interaction site, contributing to the strength and specificity of the interaction. The crystallographically defined interface is shown to be consistent with results of studies using site-directed NuiA mutants. This mode of inhibition differs dramatically from the exosite mechanism of inhibition seen with the DNase colicins E7/E9 and from other nuclease-inhibitor complexes that have been studied. The structure of this complex provides valuable insights for the development of inhibitors for related nonspecific nucleases that share the DRGH active site motif such as the Streptococcus pneumoniae nuclease EndA, which mediates infectivity of this pathogen, and mitochondrial EndoG, which is involved in recombination and apoptosis.

Sugar non-specific endonucleases

Sugar non-specific endonucleases are multifunctional enzymes and are widespread in distribution. Apart from nutrition, they have also been implicated in cellular functions like replication, recombination and repair. Their ability to recognize different DNA structures has also been exploited for the determination of nucleic acid structure. Although more than 30 non-specific endonucleases have been isolated to date, very little information is available regarding their structure-function correlations except that of staphylococcal and Serratia nucleases. However, during the past few years, the primary structure, nature of the active site based on sequence homology, and the probable mechanism of action have been postulated for some of the enzymes. This review describes the purification, characteristics, biological role and applications of sugar non-specific endonucleases.

RNAi as random degradative PCR: siRNA primers convert mRNA into dsRNAs that are degraded to generate new siRNAs

In posttranscriptional gene silencing (PTGS), "quelling," and RNA interference (RNAi), 21-25 nucleotide RNA fragments are produced from the initiating dsRNA. These short interfering RNAs (siRNAs) mediate RNAi by an unknown mechanism. Here, we show that GFP and Pp-Luc siRNAs, isolated from a protein complex in Drosophila embryo extract, target mRNA degradation in vitro. Most importantly, these siRNAs, as well as a synthetic 21-nucleotide duplex GFP siRNA, serve as primers to transform the target mRNA into dsRNA. The nascent dsRNA is degraded to eliminate the incorporated target mRNA while generating new siRNAs in a cycle of dsRNA synthesis and degradation. Evidence is presented that mRNA-dependent siRNA incorporation to form dsRNA is carried out by an RNA-dependent RNA polymerase activity (RdRP).

Experimental evaluation of the ribonuclease protection assay method for the assessment of genetic heterogeneity in populations of RNA viruses

The ribonuclease (RNase) protection assay (RPA) was evaluated as a method to estimate genetic distances among sequence variants of RNA viruses. The patterns of fragments generated, under different RPA conditions, by three sets of RNA sequence variants of known nucleotide sequence, were analyzed. Both the effectiveness of cleavage (i.e. the probability of cleavage in a certain heteroduplex) and its degree (i.e. in all the molecules in the assay or in a part of them) varied largely according to the nature of the mismatch. Probability and degree of cleavage were also dependent on distant sequence context effects. No correlation could be established between context and cleavage, so that the pattern of fragments in RPA cannot be unequivocally predicted from sequence information. Accordingly, nucleotide sequence differences between two sequence variants cannot be directly derived from RPA data. For all three sequence sets linear relationships were found between the number of non-shared fragments in the RPAs of two variants and their nucleotide sequence differences. Nevertheless, both linearity and the linear regression parameters varied largely according to the sequence set and according to RPA conditions, in a non-predictable way. Thus, under experimental conditions, RPA may not be as appropriate a method to estimate genetic distances between RNA sequences as simulation under an ideal model suggested. Possible ways to diminish the gap between the ideal model and the experimental procedure are proposed.

Xenopus Ro ribonucleoproteins: members of an evolutionarily conserved class of cytoplasmic ribonucleoproteins

Ro small ribonucleoproteins consist of a 60-kDa protein and possibly additional proteins complexed with several small RNA molecules. The RNA components of these particles, designated Y RNAs, are about 100 nt long. Although these small ribonucleoproteins are abundant components of a variety of vertebrate species and cell types, their subcellular location is controversial, and their function is completely unknown. We have identified and characterized the Ro RNPs of Xenopus laevis. Three of the four distinct Xenopus Y RNAs appear to be related to the previously sequenced human hY3, hY4, and hY5 RNAs. The fourth Xenopus Y RNA, xY alpha, does not appear to be a homologue of any of the human Y RNAs. Each of the human and Xenopus Y RNAs possesses a conserved stem that contains the binding site for the 60-kDa Ro protein. Xenopus and human 60-kDa Ro proteins are 78% identical in amino acid sequence, with the conservation extending throughout the entire protein. When human hY3 RNA is mixed with Xenopus egg extracts, the human RNA assembles with the Xenopus Ro protein to form chimeric Ro ribonucleoproteins. By analyzing RNA extracted from manually enucleated oocytes and germinal vesicles, we have determined that Y RNAs are located in the oocyte cytoplasm. By examining the distribution of mouse Ro ribonucleoproteins in cytoplast and karyoplast fractions derived from L-929 cells, we have determined that Ro ribonucleoprotein particles also primarily reside in the cytoplasm of mammalian cells.

Ribosomal movement impeded at a pseudoknot required for frameshifting

Translational frameshifting sometimes occurs when ribosomes encounter a "shift" site preceding a region of unusual secondary structure, which in at least three cases is known to be a pseudoknot. We provide evidence that ribosomes have a decreased rate of movement through a pseudoknot required for frameshifting. These paused ribosomes are directly situated over the shift sequence. Ribosomal pausing appears to be necessary but not sufficient for frameshifting.

Frequent isolation of intertypic poliovirus recombinants with serotype 2 specificity from vaccine-associated polio cases

Five representatives from a collection of 21 Sabin type 2-like poliovirus strains isolated from paralytic poliomyelitis cases in two regions of the USSR have been subjected to limited nucleotide sequencing. All proved to be intertypic recombinants having the genes encoding capsid proteins of Sabin 2 origin and a 3'-end portion of the genome derived from either type 1 (3 isolates) or type 3 (2 isolates) Sabin strains. The crossover points in all the 5 genomes have been mapped to different loci of the P3 region. At least 6 additional isolates from the same collection (and 2 isolates from healthy contacts), appeared to have a type 2/type 1 recombinant genome, as judged by oligonucleotide mapping. The biological significance of frequent occurrence of recombinants among field isolates of vaccine-related strains is discussed.

RNA mediated formation of a phosphorothioate diester bond

Previous results showed that multimeric, tandemly sequence-repeated forms of satellite tobacco ringspot virus RNA of the encapsidated polarity (STobRV (+)RNA) autolytically process at a specific phosphodiester bond, the junction. Substituting a phosphorothioate diester bond for the STobRV (+)RNA junction drastically slowed autolytic processing. Here we show that for the complementary STobRV (-)RNA, in contrast, replacing sets of phosphodiester bonds with phosphorothioate diester bonds, even at the junction, did not greatly slow autolytic processing or spontaneous ligation, the usual reactions of the unmodified RNA. In the ligation reaction STobRV (-)RNA directed the formation of an ApG phosphorothioate diester bond.

Intron sequences and the length of the downstream second exon affect the binding of hnRNP C proteins in an in vitro splicing reaction

The proteins that are in direct contact with the pre-mRNA in an in vitro splicing reaction were analyzed by UV cross-linking experiments. Six major proteins (120, 55, 44, 42, 39 and 38 KD) and three minor polypeptides (84, 72 and 63 KD) were detected. The predominant proteins 44, 42 KD belong to the class of hnRNP C proteins since they were immunoprecipitated by monoclonal antibodies directed against hnRNP C proteins. The cross-linked proteins were not detected in the absence of Mg2+, ATP or when RNA lacking introns were used as substrates in the splicing reactions. The effect of exon sequences on the binding efficiency for the photocrosslinked proteins was investigated. Transcripts containing a second exon of 24 nucleotides for the beta-globin or 107 nucleotides for the mouse insulin, yielded a reduced amount of cross-linked proteins when compared with "full length" pre-mRNAs. Sequences within the first exon of the beta-globin pre-mRNA did not affect the binding efficiency of these proteins. The reduced binding efficiency of the cross-linked proteins for the truncated beta-globin or mouse insulin pre-mRNAs correlated with the lower efficiency for in vitro splicing. Substitutions with unrelated sequences in the beta-globin second exon restore the binding of the cross-linked proteins indicating that the length of the second exon and not specific sequences are relevant for the binding efficiency of these proteins. The SP6/mouse insulin oligonucleotides cross-linked to the hnRNP C proteins were isolated and sequenced. A 17-mer was located in the second exon (134 nucleotides downstream from the 3' splice site) and a 14-mer in the intron region (25 nucleotides downstream the 5' splice site). The beta-globin oligonucleotides cross-linked to the hnRNP C proteins were a 13-mer in the second exon (28 nucleotides downstream the 3' splice site) and an 8-mer in the first exon (81 nucleotides downstream the 5' end of the pre-mRNA). Our results indicate that the hnRNP C proteins interact with those oligonucleotides located in different regions of the pre-mRNA. The binding efficiency of those proteins, however, depends on the length of the second exon and the presence of intron sequences (secondary and/or tertiary pre-mRNA structure).

Human SS-B/LA autoantigen contains a covalent protein-RNA linkage

The chemical nature of association of RNA in immunoprecipitates of human SS-B/La ribonucleoprotein, an autoantigen expressed in various autoimmune disorders, was investigated. A fraction of RNA associated with SS-B/La immunoprecipitates was readily dissociated by SDS-polyacrylamide gel electrophoresis, yielding four main subfractions, R1-4, with chain lengths in the range of 90-130 nucleotides (R4), 140-175 nucleotides (R2 and R3) and above 200 nucleotides (R1). Moreover, the immunoreactive protein component, migrating with a molecular mass of 49 kDa, contained a very tightly bound RNA co-migrating with the protein unless the protein was proteolytically degraded. Most of the RNA molecules in this fraction, represented by about 20 components, had a free 3'-terminus but a blocked 5'-terminus and showed chain lengths between 10 and 125 nucleotides. After pretreatment with alkaline phosphatase and a mixture of ribonucleases T1 + T2 + A, adenosine 3',5'-biphosphate (pAp) was liberated by phosphodiesterase (Crotalus durissus) as the blocked 5'-end of the RNA. The chemical nature of the blockage was revealed after alternative treatment of the protein-pAp component with phosphodiesterase or nuclease S7 followed by acid hydrolysis and phosphoamino acid analysis which showed that a threonine residue must be directly involved in the RNA-protein linkage of 49 kDa SS/La antigen, indicating the presence of a covalent threonine-pAp bond.

A simple and rapid solid-phase RNA sequencing method

A simple and rapid solid-phase RNA sequencing method has been developed based on Peattie's direct chemical method. 3'-Terminally labeled RNA was immobilized on DEAE-cellulose sheets and followed by specific modification with dimethyl sulfate, diethylpyrocarbonate, hydroxylamine (at pH 10 for the uridine and pH 5.5 for the cytidine reaction), and cleavage reaction with aniline. RNA fragments were washed from the DEAE-cellulose sheets using salt solutions, precipitated with ethanol, and separated by 15% polyacrylamide gel electrophoresis. Due to the complete removal of the impurities normally present in the solution method, the higher resolution of the sequencing bands and lower background on the autoradiograph make this solid-phase technique more efficient. This solid-phase technique is much faster and more convenient than the original method.

Purification of individual tRNAs using a monoclonal anti-AMP antibody affinity column

A murine monoclonal anti-AMP antibody affinity matrix was used for isolation of individual species of amino acid transfer nucleic acids (tRNAs). The antibodies had been prepared using 5'-AMP covalently attached to bovine serum albumin as antigen and exhibited high affinity for 5'-AMP but greatly reduced affinity for 3'-AMP. Native uncharged tRNAs that terminate in a 5'-AMP group on the amino acid acceptor arm of the molecule bind tightly to the anti-AMP affinity matrix, whereas aminoacylated tRNAs are not retained. This allows separation of a particular tRNA species as its aminoacyl derivative from a complex mixture of uncharged tRNAs under very mild conditions.

Nucleotide sequence and newly formed phosphodiester bond of spontaneously ligated satellite tobacco ringspot virus RNA

The satellite RNA of tobacco ringspot virus (STobRV RNA) replicates and becomes encapsidated in association with tobacco ringspot virus. Previous results show that the infected tissue produces multimeric STobRV RNAs of both polarities. RNA that is complementary to encapsidated STobRV RNA, designated as having the (-) polarity, cleaves autolytically at a specific ApG bond. Purified autolysis products spontaneously join in a non-enzymic reaction. We report characteristics of this RNA ligation reaction: the terminal groups that react, the type of bond in the newly formed junction and the nucleotide sequence of the joined RNA. The nucleotide sequence of the ligated RNA shows that joining of the reacting RNAs restored an ApG bond. The junction ApG has a 3'-to-5' phosphodiester bond. Thus the net ligation reaction of STobRV (-)RNA is the precise reversal of autolysis. We discuss this new type of RNA ligation reaction and its implications for the formation of multimeric STobRV RNAs during replication.

Conformational analysis of hairpin oligodeoxyribonucleotides by a single-strand-specific nuclease

Hairpin-forming oligodeoxynucleotides d[ATCCTA(A)NTAGGAT] with n = 3-6 were subjected to nuclease digestion with the nuclease from mung bean. Cleavage occurs only in the loop region of the hairpin molecules. In detail, the number and intensity of cleavage sites were determined in relation to the length of the loop, the temperature and the salt concentration. The restricted accessibility of mung bean nuclease to the loop bases adjacent to the helical region of all hairpins is due to a reduced exposure of these bases in presence of a certain Mg2+ concentration. With increasing temperature the exposure of these bases is increased. It is deduced that the bases adjacent to the helix increase the length of the latter by stacking, the degree of which is dependent on the number of loop bases.

Self-cleavage of plus and minus RNA transcripts of avocado sunblotch viroid

Self-cleavage of both plus and minus RNA transcripts of the 247-residue avocado sunblotch viroid (ASBV), prepared from tandem dimeric cDNA clones, occurs specifically at two sites in each transcript to give monomeric plus and minus species. The cleavage reaction occurs both during transcription and on incubation of purified transcripts at pH 8 and 37 degrees C in the presence of magnesium ions to give a 3'-terminal 2',3'-cyclic phosphate and a 5'-terminal hydroxyl group. Although the self-cleavage occurs at different sites in the ASBV molecule for the plus and minus species, very similar secondary structures with high sequence homology can be drawn at each site. The results are considered to provide further evidence that ASBV is replicated in vivo by a rolling circle mechanism involving non-enzymic cleavage of high molecular weight RNA precursors of ASBV.

Recombinants between attenuated and virulent strains of poliovirus type 1: derivation and characterization of recombinants with centrally located crossover points

Recombinants with a centrally located crossover point were selected from crosses between poliovirus type 1 strains and intertypic (type 3/type 1) recombinants. Two such recombinants were characterized in some detail. In one of them (v1/a1-6), the 5' half of the genome was derived from a virulent type 1 strain, while the 3' half came from an attenuated type 1 strain. The genome of the other recombinant (a1/v1-7) had the reverse organization, with the 5' and 3' halves being derived from the type 1 attenuated and virulent strains, respectively. As deduced from the RNase T1 oligonucleotide maps, the a1/v1-7 genome also had a relatively short centrally located insert of the poliovirus type 3 origin. Both recombinants exhibited ts phenotypes. The RNA phenotypes of the recombinants corresponded to that of the parent donating the 3' half of the genome, v1/a1-6 and a1/v1-7 expressing RNA- and RNA +/- characters, respectively. Despite being a ts RNA- virus, v1/a1-6 proved to be neurovirulent when injected intracerebrally into Cercopithecus aethiops monkeys, although it exhibited a somewhat diminished level of pathogenicity as compared to its virulent type 1 parent. Recombinant a1/v1-7 behaved as an attenuated strain. These data supported our previous conclusion drawn from the experiments with intertypic poliovirus recombinants that the attenuated phenotype of poliovirus depends largely on the structure of the 5' half of its genome, although mutations of the 3' half may alleviate the virulence of the virus to a degree.

A selenium-containing nucleoside at the first position of the anticodon in seleno-tRNAGlu from Clostridium sticklandii

In previous studies, the single selenonucleoside component of a selenium-containing tRNAGlu isolated from Clostridium sticklandii has been shown to be 5-methyl-aminomethyl-2-selenouridine. Here, we show that this selenonucleoside is most likely located at the "wobble" position of the anticodon of the clostridial seleno-tRNAGlu. Nuclease T1 digestion of this seleno-tRNAGlu generated one major selenium-containing oligonucleotide (25 bases long). The selenium-containing residue within this oligonucleotide was located by sequence analysis of the oligonucleotide before and after removal of selenium by treatment with cyanogen bromide. The sequence of this oligonucleotide, A-A-C-C-G-C-C-C-U-U+-U-C-A+C-G-G-C-G-G-U-A-A-C-A-G, is homologous to that of the Escherichia coli tRNAGlu2 from residues 27 to 50, including the anticodon region and the variable loop, except that the E. coli tRNA has 5-methylaminomethyl-2-thiouridine instead of the selenonucleoside.

Complete nucleotide sequence of RNA 3 from alfalfa mosaic virus, strain S

We report the sequence of RNA 3 from strain S of Alfalfa mosaic virus (2,055 nucleotides). This RNA codes for a 32.4 kd protein (P3) and for the 24 kd coat protein (P4). The largest part of the sequence was established using RNA sequencing methods. The completion of the sequence in the region coding for P3 was achieved with cloned cDNA synthesized after priming at internal sites of RNA 3. Comparison of the RNA sequences coding P3 and P4 proteins in strain S with those reported in the literature for strain 425 revealed a higher amino acid substitution rate (3%) for P3 than for P4 (congruent to 1%) despite a similar average base substitution of 3-4% in these regions. In P3, two out of nine amino acid changes occur in hydrophilic regions. The amino acid changes in P4 do not modify the local hydrophilicity distribution. The intercistronic region displays a low degree of base substitution (2%) when compared with the untranslated 3'-end region (3.6%) or the 5'-end leader region (8%), the average substitution rate being 3.2%.

Characterization of the autoimmune antigenic determinant for ribonucleoprotein (RNP) antibody

Small nuclear ribonucleoprotein complexes are antigens in various autoimmune diseases. The serological pattern of high titers of circulating antibody to nuclear ribonucleoprotein (RNP) antigen is a diagnostic marker for mixed connective tissue disease (MCTD); whereas antibody to Sm is prevalent in systemic lupus erythematosus (SLE). Both calf thymus and rabbit thymus are commonly used, excellent sources for preparation of the corresponding antigens RNP and Sm in clinical and research laboratories (A. M. Boak et al., accompanying paper). Thus, biochemical and structural characterization of the minimal antigenic determinant in these preparations is important for its use in the laboratory, as well as significant for understanding MCTD, SLE, and other examples of autoimmunity. Purification and biochemical analyses of immunologically active RNP from many different preparations of calf thymus extract has revealed that the majority of antibody in monospecific MCTD patient sera recognizes an antigen composed of the 165 nucleotide RNA, U1 RNA, and five peptides. Calf thymus U1 RNA was found to be identical in sequence to that of man. A sequence of 55 nucleotides within the 165 nucleotide RNA was the minimal RNA fragment found in RNP particles that were still immunologically active. Two of the RNP peptides react with patient sera monospecific for RNP and thus, are presumably the antigenic peptides complexed with the 55 nucleotide RNA sequence.

Structural similarities between viroids and transposable genetic elements

The primary structures of the tomato planta macho and tomato apical stunt viroids have been determined, and probable secondary structures are proposed. Both viroids can assume the rodlike conformation with extensive base-pairing characteristic of all known viroids. Sequence homologies between the two viroids (75%) and with members of the potato spindle tuber viroid group (73-83%) indicate that they both belong to this group. Comparative sequence analysis of all members of the group reveals striking similarities with the ends of transposable genetic elements. These similarities, the presence of inverted repeats often ending with the dinucleotides U-G and C-A, and flanking imperfect direct repeats suggest that viroids may have originated from transposable elements or retroviral proviruses by deletion of interior portions of the viral (or element) DNA.

Structure of the 5'-terminal untranslated region of the genomic RNAs from two strains of alfalfa mosaic virus

We report the sequences of the 5'-terminal regions of the 3 Alfalfa Mosaic Virus genomic RNAs for the Strasbourg strain (AlMV-S) and for a new isolate, AlMV-B; they are compared to similar data obtained by Koper-Zwarthoff et al. (Nucleic Acids Res. 1980, 8, 5635-5647) for strain 425. The structure of these leaders is highly conserved in RNAs 1 and 2. The length of the leader is 102, 100 and 101 nucleotides in RNA1 for strains S, B and 425 respectively; 55 and 56 in RNA2 for strains S and B respectively. In RNA3 however, there are important differences near the 5'-terminus between strain S and the other two: The total leader length is 258 nucleotides for strain S and 242 for strain B. The secondary structure models show a conserved hairpin near the 5'-end of each genomic RNA of AlMV-S. This hairpin is inexistent in RNA3 of the B and 425 strains. The degree of base-pairing increases with leader length. The initiator codon is located in a single stranded region in RNA2 whereas it is found in a hairpin stem in RNA 3.

Sequence determination of the (+) leader RNA regions of the vesicular stomatitis virus Chandipura, Cocal, and Piry serotype genomes

Using 3'-end-labeled genome probes, cells infected with vesicular stomatitis virus Chandipura, Cocal, and Piry serotypes were shown to contain (+) leader RNAs of approximately 50 nucleotides in length. The nucleotide sequence of the leader RNA regions of these genomes was determined and compared with the previously reported sequences of both the (+) and (-) leader RNA regions of other vesicular stomatitis virus serotypes. Regions of strong conservation of nucleotide sequence among the various vesicular stomatitis virus serotypes suggest those nucleotides thought to be involved in control functions during vesicular stomatitis virus replication.

The in vitro and in vivo inactivation of ribosomes by virginiamycin M does not entail an alteration of 5, 16 and 23 S ribosomal RNA

The M component of virginiamycin blocks protein synthesis by inactivating catalytically the 50 S ribosomal subunits: the in vitro interaction of 50 S with virginiamycin M, followed by removal of the antibiotic, results in a lasting damage of the particle. This enzyme-like inactivation of 50 S subunits resembles that of 30 S subunits by colicin E3, which entails the cleavage of 16 S rRNA. To explore this possibility, rRNA obtained from particles incubated in vivo and in vitro with virginiamycin M were analyzed. Electrophoretic analysis of 5, 16 and 23 S rRNA did not reveal major changes, nor did it show the appearance of additional fragments. To exclude the possibility of terminal alterations, the 5'- and 3'-extremities of these RNA were also sequenced and found unchanged. Conclusions drawn in the present work parallel those of an accompanying paper (Moureau, P., Di Giambattista, M. and Cocito, C. (1983) Biochim. Biophys. Acta 739, 164-172) describing the dissociation and reassociation of ribosomes incubated with virginiamycin M: the lasting ribosome damage by this antibiotic appears to be due to a conformational rather than to a structural alteration.

Coat protein binding sites on RNA 1 of alfalfa mosaic virus

The largest genome segment, RNA 1, of alfalfa mosaic virus forms complexes with viral coat protein. These complexes were subjected to digestion with ribonucleases T1 or A and filtered onto Millipore filters. Specific fragments were collected from the filters by phenol extraction. After electrophoretic separation in denaturing polyacrylamide gels, these fragments were sequenced. Besides extracistronic fragments originating from the 3'-terminal region of RNA 1, fragments were found originating from an intracistronic region of the RNA. A striking phenomenon is that the intracistronic fragments were not found when ribonuclease A was used to degrade RNA/protein complexes. The findings are in agreement with the postulation of Houwing and Jaspars (1978), that a conformational change at the 3' ends of the genome RNAs induced by the coat protein is a prerequisite to start an infection cycle.

The nucleotide sequence of 5.8S rRNA from the posterior silk gland of the silkworm Philosamia cynthia ricini

The nucleotide sequence of 5.8S rRNA from the Chinese silkworm Philosamia cynthia ricini has been determined by gel sequencing and mobility shift methods. The complete primary structure is (sequence in text). This is one of the largest known 5.8S rRNAs. As compared to Bombyx 5.8S rRNA, it is two nucleotides longer; two nucleotides near the 5'end and two nucleotides near the 3'end are different, and psi 61 of the Bombyx RNA sequence is an unmodified U in Philosamia RNA. The secondary structure of Philosamia 5.8S rRNA may differ from the Bombyx RNA structure by three additional base pairs at the 5'/3' ends.

Protein binding sites in nucleation complexes of alfalfa mosaic virus RNA 4

The subgenomic coat protein messenger RNA 4 of alfalfa mosaic virus forms complexes with one and three coat protein dimers, which are designated complexes I and III, respectively. These complexes were separated, subjected to digestion with ribonuclease T1, and filtered onto Millipore filters. Phenol extracts of the filters contained specific fragments of RNA 4, which were sequenced after electrophoretic separation on nondenaturing and denaturing polyacrylamide gels. Complex I yielded only a 68-nucleotide fragment including the 3' terminus [fragment 814-881 according to the numbering of Brederode, F. Th., Koper-Zwarthoff, E. C., & Bol, J. F. (1980) Nucleic Acids Res. 8, 2213-2223]. Complex III yielded in addition to the former fragment also other, mostly extracistronic, fragments from the 3'-terminal region, as well as fragments from an intracistronic region, comprising positions 425-474, in the middle of RNA 4. The 3'-terminal region was subdivided by small gaps into three coat protein binding sites: 799-881, 759-787, and 667-753, designated sites 1, 2, and 3, respectively, and possibly representing the sites occupied by the three coat protein dimers. A similarity may exist between the secondary structure of sites 1 and 3, which both may have three hairpins, two of which flanked at their 3' side by an AUGC sequence. Furthermore, a complementarity was noted between the loop of a large hairpin which can be drawn in the intracistronic site and the upper part of one of the three hairpins in the 3'-terminal site 1. These binding features have been combined in a model structure for the complex of RNA 4 with three coat protein dimers.

Nucleotide sequence of the 5'- and 3'- domains for rabbit 18S ribosomal RNA

By direct RNA sequence analysis we have determined the primary structures of both the 5' and 3' domains for rabbit 18S ribosomal RNA. Purified 18S rRNA was labeled in vitro at either its 5' or 3' terminus with 32P, base-specifically fragmented enzymatically and chemically, and the resulting fragments electrophoretically fractionated by size in adjacent lanes of 140 cm long polyacrylamide sequencing gels run in 90% formamide. A phylogenetic comparison of both the mammalian 5' proximal 400 residues and the 3' distal 301 nucleotides with the previously determined yeast and Xenopus laevis 18S rRNA sequence shows extensive conservation interspersed with tracts having little homology. Clusters of G + C rich sequences are present within the mammalian 5' domain which are entirely absent in both the Xenopus laevis and yeast 18S rRNAs. Most base differences and insertions within the mammalian 18S rRNA when compared with yeast or Xenopus rRNA result in an increase in the G + C content of these regions. We have found nucleotide sequence analysis of the ribosomal RNA directly permits detection of both cistron heterogeneities and mapping of many of the modified bases.

Species specificity of promoter recognition by RNA polymerase and its transfer by the sigma factor

RNA polymerase holoenzyme from Micrococcus luteus synthesizes in vitro a run-off transcript of 85 nucleotides from a DNA fragment containing part of gene E of bacteriophage phi X174. This RNA starts with GTP as the 5' terminus 18 nucleotides downstream from the start of gene E on the viral (+)strand. Transcription does not occur when the fragment is cleaved 36 nucleotides upstream of the initiation site. No transcript is obtained with RNA polymerase core or holoenzyme from Escherichia coli. Other DNA fragments containing the three major E. coli promoters of phi X174 are transcribed by both enzymes although much less efficiently by M. luteus RNA polymerase. When subunit sigma in E. coli RNA polymerase is replaced by sigma from M. luteus the resulting hybrid enzyme actively transcribes the DNA fragment containing the inner region of gene D with formation of the same run-off transcript which is obtained with M. luteus holoenzyme. In the presence of sigma from E. coli this RNA is not synthesized. The hybrid enzyme also transcribes a DNA fragment containing the gene A promoter of phi X174 with even higher efficiency than RNA polymerase holoenzyme from E. coli.

Nucleotide sequence and secondary structure of citrus exocortis and chrysanthemum stunt viroid

The complete nucleotide sequence of citrus exocortis viroid (CEV, propagated in Gymura) and chrysanthemum stunt viroid (CSV, propagated in Cineraria) has been established, using labelling in vitro and direct RNA sequencing methods and a new screening procedure for the rapid selection of suitable RNA fragments from limited digests. The covalently closed circular single-stranded viroid RNAs consist of 371 (CEV) and 354 (CSV) nucleotides, respectively. As previously shown for potato spindle tuber viroid (PSTV, 359 nucleotides), CEV and CSV also contain a long polypurine sequence. Maximal base-pairing of the established CEV and CSV sequences results in an extended rod-like secondary structure similar to that previously established for PSTV and as predicted from detailed physicochemical studies of all these viroids. Although the three viroid species sequenced to date differ in size and nucleotide sequence, there is 60--73% homology between them. As PSTV, CEV and CSV also contain conserved complementary sequences which are separated from each other in the native secondary structure. We postulate that the resulting 'secondary' hairpins, being formed and observed in vitro during the complex process of thermal denaturation of viroid RNA, must have a vital, although yet unknown, function in vivo. The possible origin and function of viroids are discussed on the basis of the characteristic structural features and of a considerable homology with U1a RNA found for a region highly conserved in the three viroids.

Avocado sunblotch viroid: primary sequence and proposed secondary structure

The sequence of the 247 nucleotide residues of the single strand circular RNA of avocado sunblotch viroid (ASBV) was determined using partial enzymic cleavage methods on overlapping viroid fragments obtained by partial ribonuclease digestion followed by 32p-labelling in vitro at their 5'-ends. ASBV is much smaller than potato spindle tuber viroid (PSTV; 359 residues) and chrysanthemum stunt viroid (CSV; 356 residues). A secondary structure model for ASBV is proposed and contains 67% of its residues base paired. In contrast to the extensive (69%) sequence homology of CSV with PSTV, only 18% of the ASBV sequence is homologous to PSTV and CSV. There are eight potential polypeptide translation products with chain lengths from 4 to 63 amino acid residues coded for by the plus (infectious) strand and four potential translation products (2 to 60 residues) coded for by the minus strand. An improved method is described for the synthesis of gamma-32p-ATP of high specific activity.

Altered features in the secondary structure of Vicia faba 5.8s rRNA

We have re-examined the nucleotide sequence of Vicia faba (broad bean) 5.8S rRNA using partial chemical degradation and a new approach to high temperature (65-80 degrees C) sequencing gels. The results indicate that the secondary structure was not completely disrupted in previous studies (Tanaka, Y., Dyer, T.A. and Brownlee, G.G. (1980) Nucleic Acid Res. 8, 1259-1272) and explain ambiguities between the nucleotide sequence and T1 ribonuclease digests. Despite this revision, estimates in the secondary structure suggest that this 5.8S rRNA differs from previously examined examples in two respects, more open conformations in both the "GC-rich" and "AU-rich" stems. The secondary structure was probed under a variety of ionic conditions using limited pancreatic and T1 ribonuclease digestion and rapid gel sequencing techniques. These studies and theoretical considerations generally supported the "burp gun" model previously proposed for all 5.8S rRNAs and were inconsistent with the recently suggested "cloverleaf" configuration. More importantly, they were also consistent with more open stem structures in this higher plant.

Mapping tRNA structure in solution using double-strand-specific ribonuclease V1 from cobra venom

A method for mapping all base-paired stems in both elongation and initiator tRNAs is described using double-stranded-specific ribonuclease V1 from the venom of the cobra Naja naja oxiana. 32p-end-labeled RNA is first partially digested with double-strand-specific V1 nuclease under near physiological conditions, and the resultant fragments are than electrophoretically fractionated by size in adjacent lanes of a polyacrylamide gel run in 90% formamide. After autoradiography, the base-paired nucleotides are definitively located by comparing V1 generated bands with fragments of known length produced by both Neurospora endonuclease and base-specific ribonucleases. Using the substrates yeast tRNAPhe an E, coli tRNAfMet of known three-dimensional structure, we find V1 nuclease to cleave entirely within every base-paired stem. Our studies also reveal that nuclease V1 will digest paired nucleotides not hydrogen-bonded by standard Watson-Crick base-pairing. In yeast tRNAPhe cleavage of both wobble base-pairs and nucleotides involved in tertiary base-base hydrogen bonding is demonstrated.

Structure and properties of a bovine liver UGA suppressor serine tRNA with a tryptophan anticodon

A bovine liver serine tRNA with a variety of unusual features has been sequenced and characterized. This tRNA is aminoacylated with serine, although it has a tryptophan anticodon CmCA. In ribosome binding assays, this tRNA (tRNASERCmCA) binds to the termination codon UGA and shows little or no binding in response to a variety of other codons including those for tryptophan and serine. The unusual codon recognition properties of this molecule were confirmed in an in vitro assay where this tRNA suppressed UGA termination. This is the first naturally occurring eucaryotic suppressor tRNA to be so characterized. Other unusual features, possibly related to the ability of this tRNA to read UGA, are the presence of two extra nucleotides, compared to all other tRNAs, between the universal residues U at position 8 and A at position 14 and the presence of an extra unpaired nucleotide within the double-stranded loop IV stem. This tRNA is also the largest eucaryotic tRNA sequenced to date (90 nucleotides). Despite its size, however, it contains only six modified residues, tRNASerCmCA shows extremely low homology to other mammalian serine (47-52% homology) or tryptophan (49% homology) tRNAs.

Chrysanthemum stunt viroid: primary sequence and secondary structure

The sequence of the 356 nucleotide residues of chrysanthemum stunt viroid (CSV) has been determined. Overlapping linear viroid fragments were obtained by partial ribonuclease digestion, radiolabelled in vitro at their 5'-ends, and sequenced using partial enzymic cleavage methods. Of the CSV sequence, 69% is contained in the published sequence of potato spindle tuber viroid (PSTV). Differences in the primary sequence of CSV and PSTV suggest that neither the positive nor putative negative strands of these two viroids code for functional polypeptide products. However, the two viroids can form similar secondary structures, implicating a role for viroid structure in replication.

Dispersed 5S RNA genes in N. crassa: structure, expression and evolution

The 5S RNA genes (5S genes) in N. crassa are not tandemly arranged or tightly clustered as in other eucaryotes that have been examined. 55 RNA or cloned 5S DNA hybridizes to at least 30 different restriction fragments of Neurospora DNA. Of 34 5S DNA clones examined, each contains a single 5S gene. Saturation hybridization analyses indicate that there are about 100 copies of 5S genes in the genome of this organism. We have partially or completely sequenced the 5S region of 15 clones. Both identical and highly divergent 5S coding regions were found. Nine are of one type (alpha). The other six include four different types (beta, beta', gamma and delta) which differ from each other and from the alpha genes to various degrees. Eleven of 15 genes have distinct flanking regions. Analysis of Neurospora 5S RNA showed that it consists of one principal species which matches the alpha-type gene sequence. Additional 5S species corresponding to the less abundant 5S gene types were also detected. The pattern of nucleotide substitutions between the predicted Neurospora 5S RNAs and between these and S. cerevisiae 5S RNA suggests that a particular 5S RNA secondary structure occurs in vivo and is conserved.