Tiina Tamm

Characterization of cocksfoot mottle sobemovirus genomic RNA and sequence comparison with related viruses

The genome of cocksfoot mottle virus (CfMV) is a positive-sense ssRNA molecule of 4082 nucleotides as revealed by sequencing the entire genome. The 5-untranslated region of the genome is 69 nucleotides and the 3-untranslated region is 225 nucleotides in length. The coding region contains four open reading frames (ORFs). The organization of CfMV ORFs differs significantly from that of the previously sequenced sobemoviruses southern bean mosaic virus and rice yellow mottle virus. ORF1 encodes a protein having a calculated molecular mass of 12.3 kDa. The function of this protein is unknown. The next ORF codes for the putative VPg and serine protease. The ORF2a product consists of 568 amino acids, with a calculated molecular mass of 60.9 kDa. The replicase of CfMV is translated as part of a polyprotein by--1 ribosomal frameshifting in ORF2a. The calculated molecular mass of the transframe protein is 103.4 kDa. ORF3 encodes the 27.6 kDa coat protein. This has been verified by amino acid sequencing of the CfMV coat protein N terminus. Northern blots of total RNA from CfMV-infected barley leaves reveal the 4.1 kb genomic RNA band and one virus-specific band of 1.2 kb, which may represent a subgenomic RNA for coat protein synthesis.

Characterization of VPg and the polyprotein processing of Cocksfoot mottle virus (genus Sobemovirus)

The polyprotein of Cocksfoot mottle virus (CfMV; genus SOBEMOVIRUS:) is translated from two overlapping open reading frames (ORFs) 2a and 2b by a -1 ribosomal frameshifting mechanism. In this study, a 12 kDa protein was purified from viral RNA-derived samples that appears to correspond to the CfMV genome-linked protein (VPg). According to the determined N-terminal amino acid sequence, the VPg domain is located between the serine proteinase and replicase motifs and the N terminus of VPg is cleaved from the polyprotein between glutamic acid and asparagine residues. Western blot analysis of infected plant material showed that the polyprotein is processed at several additional sites. An antiserum against the ORF 2a product recognized six distinct proteins, whereas, of these, the VPg antiserum clearly recognized only a 24 kDa protein. This indicates that the fully processed 12 kDa VPg detected in viral RNA-derived samples is a minor product in infected plants. An antiserum against the ORF 2b product recognized a 58 kDa protein, which indicates that the fully processed replicase is entirely or almost entirely encoded by ORF 2b. The origin of the detected cleavage products and a proposed polyprotein processing model are discussed.

RNA-binding activities of cocksfoot mottle sobemovirus proteins.

Cocksfoot mottle virus (CfMV) has a positive-sense ssRNA genome containing four open reading frames (ORFs). ORF1 encoded protein (P1) is the putative movement protein; the product of ORF2a (P2a) contains VPg and the motifs characteristic of serine proteases. P2b, encoded by ORF2b, is the putative RNA-dependent RNA polymerase. P3, the coat protein, is encoded by ORF3. CfMV P1, P2a, P2b, and P3, containing a six histidine tag at the amino terminus, were expressed in Escherichia coli, purified and their RNA-binding activities were analysed. The northwestern blot assay showed that His-tagged P1, P2a, P2b, and P3 were able to interact with ssRNA transcripts in a sequence-nonspecific manner. The filter-binding assay confirmed the ssRNA-binding capacity of recombinant P1, P2a, and P3. The RNA-binding activities of His-tagged P3 and native coat protein were similar. P1 and P2a binding to ssRNA decreased markedly by increasing NaCl concentrations. In contrast, P3 had the RNA-binding optimum at 100-200 mM NaCl. We discuss the possible amino acid motifs involved in the RNA-binding of CfMV proteins.

P1 Protein of Cocksfoot Mottle Virus is Indispensable for the Systemic Spread of the Virus

Cocksfoot mottle sobemovirus (CfMV) encodes a non-conserved protein P1 from the 5′ ORF1 of genomic RNA. The functions of CfMV P1 are unknown. In the current study we show that P1-deficient CfMV can replicate both in oat leaves and barley suspension culture cells but can not infect oat plants systemically. However, the absence of P1 reduces the efficiency of virus accumulation considerably. The infectivity of the mutant virus restores as a result of the spontaneous transversion. CfMV P1:EGFP shows a very limited cell-to-cell movement in leaf epidermal cells. In Sf9 insect cells CfMV P1 localizes in the fraction of membranes and inclusions but not in soluble cytoplasmic protein fraction.

Cocksfoot mottle sobemovirus coat protein contains two nuclear localization signals

Cocksfoot mottle virus (CfMV) coat protein (CP) localization was studied in plant and mammalian cells. Fusion of the full-length CP with enhanced green fluorescent protein (EGFP) localized to the cell nucleus whereas similar constructs lacking the first 33 N-terminal amino acids of CP localized to the cytoplasm. CP and EGFP fusions containing mutations in the arginine-rich motif of CP localized to the cytoplasm and to the nucleus in plant cells indicating the involvement of the motif in nuclear localization. In mammalian cells, mutations in the arginine-rich region were sufficient to completely abolish nuclear transport. The analysis of deletions of amino acid residues 1–11, 1–22, and 22–33 of CP demonstrated that there were two separate nuclear localization signals (NLS) within the N-terminus—a strong NLS1 in the arginine-rich region (residues 22–33) and a weaker NLS2 within residues 1–22. Analysis of point mutants revealed that the basic amino acid residues in the region of the two NLSs were individually not sufficient to direct CP to the nucleus. Additional microinjection studies with fluorescently labeled RNA and CP purified from CfMV particles demonstrated that the wild-type CP was capable of transporting the RNA to the nucleus. This feature was not sequence-specific in transient assays since both CfMV and GFP mRNA were transported to the cell nucleus by CfMV CP. Together the results suggest that the nucleus may be involved in CfMV infection.

Dysfunctional Mitochondria Modulate cAMP-PKA Signaling and Filamentous and Invasive Growth of Saccharomyces cerevisiae

Mitochondrial metabolism is targeted by conserved signaling pathways that mediate external information to the cell. However, less is known about whether mitochondrial dysfunction interferes with signaling and thereby modulates the cellular response to environmental changes. In this study, we analyzed defective filamentous and invasive growth of the yeast Saccharomyces cerevisiae strains that have a dysfunctional mitochondrial genome (rho mutants). We found that the morphogenetic defect of rho mutants was caused by specific downregulation of FLO11, the adhesin essential for invasive and filamentous growth, and did not result from general metabolic changes brought about by interorganellar retrograde signaling. Transcription of FLO11 is known to be regulated by several signaling pathways, including the filamentous-growth-specific MAPK and cAMP-activated protein kinase A (cAMP-PKA) pathways. Our analysis showed that the filamentous-growth-specific MAPK pathway retained functionality in respiratory-deficient yeast cells. In contrast, the cAMP-PKA pathway was downregulated, explaining also various phenotypic traits observed in rho mutants. Thus, our results indicate that dysfunctional mitochondria modulate the output of the conserved cAMP-PKA signaling pathway.

Stem-loop structure of Cocksfoot mottle virus RNA is indispensable for programmed -1 ribosomal frameshifting.

n Abstractn n The −1 programmed ribosomal frameshifting (−1 PRF) mechanism utilized by many viruses is dependent on a heptanucleotide slippery sequence and a downstream secondary structure element. In the current study, the RNA structure downstream from the slippery site of cocksfoot mottle sobemovirus (CfMV) was proven to be a 12bp stem-loop with a single bulge and a tetranucleotide loop. Several deletion and insertion mutants with altered stem-loop structures were tested in wheat germ extract (WGE) for frameshifting efficiency. The impact of the same mutations on virus infectivity was tested in oat plants. Mutations shortening or destabilizing the stem region reduced significantly but did not abolish −1 PRF in WGE. The same mutations proved to be deleterious for virus infection. However, extending the loop region to seven nucleotides had no significant effect on frameshifting efficiency in WGE and did not hamper virus replication in infected leaves. This is the first report about the experimentally proven RNA secondary structure directing −1 PRF of sobemoviruses.n n

YAP1 over‐expression in Saccharomyces cerevisiae enhances glutathione accumulation at its biosynthesis and substrate availability levels

Microbiological production of glutathione using genetically engineered yeast strains has a potential to satisfy the increasing industrial demand of this tripeptide. In the present work accumulation of glutathione in response to YAP1 over‐expression in Saccharomyces cerevisiae was studied. The over‐expression resulted in intracellular glutathione level over two times higher than in the parent strain. Transcript analyses revealed that, in addition to the genes encoding enzymes in the glutathione biosynthesis pathway (GSH1 and GSH2), the expression levels of the genes in the cysteine biosynthesis pathway (CYS3 and CYS4) were also significantly higher in the YAP1 over‐expressed strain. This suggests that YAP1 over‐expression affects glutathione accumulation at both its biosynthesis and substrate availability levels.

C-terminal extension of the yeast mitochondrial DNA polymerase determines the balance between synthesis and degradation.

Saccharomyces cerevisiae mitochondrial DNA polymerase (Mip1) contains a C-terminal extension (CTE) of 279 amino acid residues. The CTE is required for mitochondrial DNA maintenance in yeast but is absent in higher eukaryotes. Here we use recombinant Mip1 C-terminal deletion mutants to investigate functional importance of the CTE. We show that partial removal of the CTE in Mip1Δ216 results in strong preference for exonucleolytic degradation rather than DNA polymerization. This disbalance in exonuclease and polymerase activities is prominent at suboptimal dNTP concentrations and in the absence of correctly pairing nucleotide. Mip1Δ216 also displays reduced ability to synthesize DNA through double-stranded regions. Full removal of the CTE in Mip1Δ279 results in complete loss of Mip1 polymerase activity, however the mutant retains its exonuclease activity. These results allow us to propose that CTE functions as a part of Mip1 polymerase domain that stabilizes the substrate primer end at the polymerase active site, and is therefore required for efficient mitochondrial DNA replication in vivo.

Stepwise Splitting of Ribosomal Proteins from Yeast Ribosomes by LiCl

Structural studies have revealed that the core of the ribosome structure is conserved among ribosomes of all kingdoms. Kingdom-specific ribosomal proteins (r-proteins) are located in peripheral parts of the ribosome. In this work, the interactions between rRNA and r-proteins of eukaryote Saccharomyces cerevisiae ribosome were investigated applying LiCl induced splitting and quantitative mass spectrometry. R-proteins were divided into four groups according to their binding properties to the rRNA. Most yeast r-proteins are removed from rRNA by 0.5–1 M LiCl. Eukaryote-specific r-proteins are among the first to dissociate. The majority of the strong binders are known to be required for the early ribosome assembly events. As compared to the bacterial ribosome, yeast r-proteins are dissociated from rRNA at lower ionic strength. Our results demonstrate that the nature of protein-RNA interactions in the ribosome is not conserved between different kingdoms.