KnotInFrame: prediction of -1 ribosomal frameshift events

Programmed -1 ribosomal frameshift (-1 PRF) allows for alternative reading frames within one mRNA. First found in several viruses, it is now believed to exist in all kingdoms of life. Strong stimulators for -1 PRF are a heptameric slippery site and an RNA pseudoknot. Here, we present a new algorithm KnotInFrame, for the automatic detection of -1 PRF signals from genomic sequences. It finds the frameshifting stimulators by means of a specialized RNA-pseudoknot folding program, fast enough for genome-wide analyses. Evaluations on known -1 PRF signals demonstrate a high sensitivity.     

A rapid, inexpensive yeast-based dual-fluorescence assay of programmed--1 ribosomal frameshifting for high-throughput screening

Programmed -1 ribosomal frameshifting (-1 PRF) is a mechanism that directs elongating ribosomes to shift-reading frame by 1 base in the 5' direction that is utilized by many RNA viruses. Importantly, rates of -1 PRF are fine-tuned by viruses, including Retroviruses, Coronaviruses, Flavivriuses and in two endogenous viruses of the yeast Saccharomyces cerevisiae, to deliver the correct ratios of different viral proteins for efficient replication. Thus, -1 PRF presents a novel target for antiviral therapeutics. The underlying molecular mechanism of -1 PRF is conserved from yeast to mammals, enabling yeast to be used as a logical platform for high-throughput screens. Our understanding of the strengths and pitfalls of assays to monitor -1 PRF have evolved since the initial discovery of -1 PRF. These include controlling for the effects of drugs on protein expression and mRNA stability, as well as minimizing costs and the requirement for multiple processing steps. Here we describe the development of an automated yeast-based dual fluorescence assay of -1 PRF that provides a rapid, inexpensive automated pipeline to screen for compounds that alter rates of -1 PRF which will help to pave the way toward the discovery and development of novel antiviral therapeutics.     

Isolation and characterization of two alleles of the chicken cytochrome c gene.

Analysis of total chicken DNA by genomic blot hybridization indicates that only one cytochrome c gene exists in the chicken genome. The two alleles of this single cytochrome c gene have been isolated from a Charon 4A-chicken genomic library. This isolation made use of the yeast CYC1 cytochrome c gene as a specific hybridization probe. The 2 chicken alleles, CC9 and CC10, have been sequenced. The amino acid sequence predicted by these 2 alleles is identical, and agrees with the published chicken cytochrome c protein sequence. The flanking regions of these 2 alleles exhibit approximately 1% divergence, indicating a very limited polymorphism. Comparative sequence analysis with the flanking regions of previously isolated cytochrome c genes (yeast and rat) indicate no significant regions of homology. The presence of only one cytochrome c-like sequence in the chicken genome is in striking contrast with mammalian genomes, which contain as many as 20-30 cytochrome c-like sequences.     

RNA dimerization plays a role in ribosomal frameshifting of the SARS coronavirus

Messenger RNA encoded signals that are involved in programmed -1 ribosomal frameshifting (-1 PRF) are typically two-stemmed hairpin (H)-type pseudoknots (pks). We previously described an unusual three-stemmed pseudoknot from the severe acute respiratory syndrome (SARS) coronavirus (CoV) that stimulated -1 PRF. The conserved existence of a third stem–loop suggested an important hitherto unknown function. Here we present new information describing structure and function of the third stem of the SARS pseudoknot. We uncovered RNA dimerization through a palindromic sequence embedded in the SARS-CoV Stem 3. Further in vitro analysis revealed that SARS-CoV RNA dimers assemble through ‘kissing’ loop–loop interactions. We also show that loop–loop kissing complex formation becomes more efficient at physiological temperature and in the presence of magnesium. When the palindromic sequence was mutated, in vitro RNA dimerization was abolished, and frameshifting was reduced from 15 to 5.7%. Furthermore, the inability to dimerize caused by the silent codon change in Stem 3 of SARS-CoV changed the viral growth kinetics and affected the levels of genomic and subgenomic RNA in infected cells. These results suggest that the homodimeric RNA complex formed by the SARS pseudoknot occurs in the cellular environment and that loop–loop kissing interactions involving Stem 3 modulate -1 PRF and play a role in subgenomic and full-length RNA synthesis.     

Interactions of the RNA polymerase with the viral genome at the 5'- and 3'-ends contribute to 20S RNA narnavirus persistence in yeast

20S RNA narnavirus is a positive strand RNA virus found in the yeast Saccharomyces cerevisiae. The viral genome (2514 nucleotides) only encodes a single protein (p91), the RNA-dependent RNA polymerase and does not have capsid proteins to form intracellular virions. The genomic RNA has no 3' poly(A) tail and perhaps no cap structure at the 5'-end; thus resembling an intermediate of mRNA degradation. The virus, however, escapes the host surveillance and replicates in the yeast cytoplasm persistently. The viral genome is not naked but exists in the form of a ribonucleoprotein complex with p91 in a 1:1 stoichiometry. Here we investigated interactions between p91 and the viral genome. Our results indicate that p91 directly or indirectly interacts with the RNA at the 5'- and 3'-end regions and to a lesser extent at a central part. The 3'-end site is identical to or overlaps with the 3' cis signal for replication identified previously. The 5'-site is at the second stem loop structure from the 5'-end (nucleotides 72-104), and this structure also contains a cis signal for replication. Analysis of mutants in the structure revealed a tight correlation between replication and formation of complexes. These results highlight the importance of ribonucleoprotein complexes for the viral life cycle. We will discuss implications of these findings especially on how the virus escapes from mRNA degradation pathways and resides in the cytoplasm persistently despite the lack of a protective capsid.     

Endogenous assays of DNA methyltransferases: Evidence for differential activities of DNMT1, DNMT2, and DNMT3 in mammalian cells in vivo

While CpG methylation can be readily analyzed at the DNA sequence level in wild-type and mutant cells, the actual DNA (cytosine-5) methyltransferases (DNMTs) responsible for in vivo methylation on genomic DNA are less tractable. We used an antibody-based method to identify specific endogenous DNMTs (DNMT1, DNMT1b, DNMT2, DNMT3a, and DNMT3b) that stably and selectively bind to genomic DNA containing 5-aza-2'-deoxycytidine (aza-dC) in vivo. Selective binding to aza-dC-containing DNA suggests that the engaged DNMT is catalytically active in the cell. DNMT1b is a splice variant of the predominant maintenance activity DNMT1, while DNMT2 is a well-conserved protein with homologs in plants, yeast, Drosophila, humans, and mice. Despite the presence of motifs essential for transmethylation activity, catalytic activity of DNMT2 has never been reported. The data here suggest that DNMT2 is active in vivo when the endogenous genome is the target, both in human and mouse cell lines. We quantified relative global genomic activity of DNMT1, -2, -3a, and -3b in a mouse teratocarcinoma cell line. DNMT1 and -3b displayed the greatest in vivo binding avidity for aza-dC-containing genomic DNA in these cells. This study demonstrates that individual DNMTs can be tracked and that their binding to genomic DNA can be quantified in mammalian cells in vivo. The different DNMTs display a wide spectrum of genomic DNA-directed activity. The use of an antibody-based tracking method will allow specific DNMTs and their DNA targets to be recovered and analyzed in a physiological setting in chromatin.     

Fructose bisphosphatase of Saccharomyces cerevisiae. Cloning, disruption and regulation of the FBP1 structural gene

Fructose bisphosphatase catalyzes a key reaction of gluconeogenesis. We have cloned the fructose bisphosphatase (FBP1) structural gene from Saccharomyces cerevisiae by screening a genomic library for complementation of an Escherichia coli fbp deletion mutation. The cloned DNA expresses in E. coli a fructose bisphosphatase activity which is precipitable with antibodies specific for the yeast enzyme and is sensitive to inhibition by fructose 2,6-bisphosphate. Evidence is presented demonstrating that the entire gene, including all cis-acting regulatory sequences, has been cloned. A substitution mutation that disrupts FBP1 was incorporated into the yeast genome by transplacement to construct a fructose bisphosphatase null mutation. The fbp1 mutant strain is a hexose auxotroph, otherwise growing normally. Southern blot hybridization analysis confirmed the structure of the transplacement and demonstrated that FBP1 is present in single copy in the haploid genome. Northern blot hybridization analysis revealed an mRNA of about 1350 nucleotides, whose presence was repressible by glucose in the medium. Fructose bisphosphatase activity was not greatly overproduced when the FBP1 gene was present on a multicopy vector in yeast.     

Isolation and characterization of human actin genes cloned in phage lambda vectors

Using Drosophila and chicken actin probes, we have selected 14 human actin lambda recombinants from a genomic library. We present a restriction maps indicating the positions of the sequences homologous to actin and to an Alu probe. Restriction mapping has revealed that nine out of ten of these clones are distinct, indicating that actin is a multigene family. Hybrid elution of HeLa cell mRNA from filters containing the recombinant DNA, followed by in vitro translation and immunoprecipitation, as well as one- or two-dimensional protein analysis, shows that these recombinants code for actin. Hybridization back to human DNA digested with restriction enzymes shows that the EcoRI fragments of at least one of the lambda recombinants (lambda HA-5) result in similar-sized human DNA fragments in the intact genome. In nuclei, a 4.5-kb mRNA precursor to the cytoplasmic 1.9-kb mRNA can be detected by hybridization with genomic or cDNA probes, indicating the presence of additional sequences and RNA processing.     

mRNA capping enzyme. Isolation and characterization of the gene encoding mRNA guanylytransferase subunit from Saccharomyces cerevisiae.

The highly purified yeast mRNA capping enzyme is composed of two separate chains of 52 (alpha) and 80 kDa (beta), responsible for the activities of mRNA guanylyltransferase and RNA 5'-triphosphatase, respectively (Itoh, N., Yamada, H., Kaziro, Y., and Mizumoto, K. (1987) J. Biol. Chem. 262, 1989-1995). The gene encoding the mRNA guanylyltransferase subunit (alpha subunit), CEG1, has been isolated by immunological screening of a yeast genomic expression library in lambda gt11 with polyclonal antibodies directed against purified yeast capping enzyme. The identity of CEG1 was confirmed by epitope selection and by expressing the gene in Escherichia coli to give a catalytically active mRNA guanylyltransferase. The gene is present in one copy per haploid genome, and encodes a polypeptide of 459 amino acid residues. From its primary structure as well as its mRNA size, it was concluded that the alpha and the beta subunits of yeast mRNA capping enzyme are encoded by two separate genes, not as a fused protein. CEG1 is located on the chromosome VII by a pulse-field gel electrophoresis. Gene disruption experiment indicated that CEG1 is essential for the growth of yeast. We have also found another open reading frame (ORF2) which lies in close proximity to CEG1 in our clones and encodes a 450 amino acid-polypeptide of yet unknown function.     

Genome discrimination by in situ hybridization in Icelandic species of Elymus and Elytrigia (Poaceae: Triticeae).

The genome constitution of Icelandic Elymus caninus, E. alaskanus, and Elytrigia repens was examined by fluorescence in situ hybridization using genomic DNA and selected cloned sequences as probes. Genomic in situ hybridization (GISH) of Hordeum brachyantherum ssp. californicum (diploid, H genome) probe confirmed the presence of an H genome in the two tetraploid Elymus species and identified its presence in the hexaploid Elytrigia repens. The H chromosomes were painted uniformly except for some chromosomes of Elytrigia repens which showed extended unlabelled pericentromeric and subterminal regions. A mixture of genomic DNA from H. marinum ssp. marinum (diploid, Xa genome) and H. murinum ssp. leporinum (tetraploid, Xu genome) did not hybridize to chromosomes of the Elymus species or Elytrigia repens, confirming that these genomes were different from the H genome. The St genomic probe from Pseudoroegneria spicata (diploid) did not discriminate between the genomes of the Elymus species, whereas it produced dispersed and spotty hybridization signals most likely on the two St genomes of Elytrigia repens. Chromosomes of the two genera Elymus and Elytrigia showed different patterns of hybridization with clones pTa71 and pAes41, while clones pTa1 and pSc119.2 hybridized only to Elytrigia chromosomes. Based on FISH with these genomic and cloned probes, the two Elymus species are genomically similar, but they are evidently different from Elytrigia repens. Therefore the genomes of Icelandic Elymus caninus and E. alaskanus remain as StH, whereas the genomes of Elytrigia repens are proposed as XXH.