Characterization of nuclear localizing sequences derived from yeast ribosomal protein L29.

Two particular seven-amino-acid segments from yeast ribosomal protein L29 caused a non-nuclear reporter protein to associate almost exclusively with the yeast nucleus. The two L29-derived nuclear localizing sequences were identical in five of the seven residues, many of which were basic amino acids. Generally, localization of the reporter protein was most impaired by replacement of the basic residues. A particular Arg residue was unique; substitution by any amino acid including Lys diminished nuclear localization of the reporter protein. In L29 the corresponding Arg 25----Lys substitution within the nuclear localizing sequence distal to the N-terminus was without effect, as evidence by normal rates of ribosome assembly and cell growth. However, the analogous Arg 8----Lys substitution within the localizing sequence proximal to the N-terminus led to greatly reduced rates of ribosome assembly and cell growth. Finally, when both localizing sequences contained the Arg----Lys substitution a still greater decrease in ribosome assembly and cell growth was observed. These results were as expected if the two short peptide sequences functioned in nuclear localization and/or assembly of yeast ribosomal protein L29.     

Dinoflagellate phylogeny as inferred from heat shock protein 90 and ribosomal gene sequences

Background

Interrelationships among dinoflagellates in molecular phylogenies are largely unresolved, especially in the deepest branches. Ribosomal DNA (rDNA) sequences provide phylogenetic signals only at the tips of the dinoflagellate tree. Two reasons for the poor resolution of deep dinoflagellate relationships using rDNA sequences are (1) most sites are relatively conserved and (2) there are different evolutionary rates among sites in different lineages. Therefore, alternative molecular markers are required to address the deeper phylogenetic relationships among dinoflagellates. Preliminary evidence indicates that the heat shock protein 90 gene (Hsp90) will provide an informative marker, mainly because this gene is relatively long and appears to have relatively uniform rates of evolution in different lineages.

Methodology/Principal Findings

We more than doubled the previous dataset of Hsp90 sequences from dinoflagellates by generating additional sequences from 17 different species, representing seven different orders. In order to concatenate the Hsp90 data with rDNA sequences, we supplemented the Hsp90 sequences with three new SSU rDNA sequences and five new LSU rDNA sequences. The new Hsp90 sequences were generated, in part, from four additional heterotrophic dinoflagellates and the type species for six different genera. Molecular phylogenetic analyses resulted in a paraphyletic assemblage near the base of the dinoflagellate tree consisting of only athecate species. However, Noctiluca was never part of this assemblage and branched in a position that was nested within other lineages of dinokaryotes. The phylogenetic trees inferred from Hsp90 sequences were consistent with trees inferred from rDNA sequences in that the backbone of the dinoflagellate clade was largely unresolved.

Conclusions/Significance

The sequence conservation in both Hsp90 and rDNA sequences and the poor resolution of the deepest nodes suggests that dinoflagellates reflect an explosive radiation in morphological diversity in their recent evolutionary past. Nonetheless, the more comprehensive analysis of Hsp90 sequences enabled us to infer phylogenetic interrelationships of dinoflagellates more rigorously. For instance, the phylogenetic position of Noctiluca, which possesses several unusual features, was incongruent with previous phylogenetic studies. Therefore, the generation of additional dinoflagellate Hsp90 sequences is expected to refine the stem group of athecate species observed here and contribute to future multi-gene analyses of dinoflagellate interrelationships.     

Nuclear factors specifically bind to upstream sequences of a Xenopus laevis ribosomal protein gene promoter.

The upstream region of the Xenopus laevis L14 ribosomal protein gene was deleted starting from the 5' extremity in order to define the promoter length necessary to express a linked reporter CAT gene. The functional analysis indicated that a sequence located between -63 and -49 from the capsite is important for an efficient promoter activity. Band shift and ExoIII protection assays evidenced the binding to this region of a factor, called XrpFI, present in the crude nuclear extract from X.laevis oocytes. Methylation interference analysis localized the contacts in the G residues belonging to a short box, 5' CTTCC 3', positioned between -53 and -49 from the capsite. An additional factor, XrpFII, makes contacts with the sequence 5'GCCTGTTCGCC 3' located between -27 and -17 from the capsite. The deletion mutant still containing this sequence is poorly transcribed, but resumes activity when a short fragment containing the binding site for factor XrpFI is cloned in an upstream position.     

Crp1p,a new cruciform DNA-binding protein in the yeast Saccharomyces cerevisiae

A synthetic cruciform DNA (X-DNA) was used for screening cellular extracts of Saccharomyces cerevisiae for X-DNA-binding activity. Three X-DNA-binding proteins with apparent molecular mass of 28kDa, 26kDa and 24kDa, estimated by SDS-PAGE, were partially purified. They were identified as N-terminal fragments originating from the same putative protein, encoded by the open reading frame YHR146W, which we named CRP1 (cruciform DNA-recognising protein 1). Expression of CRP1 in Escherichia coli showed that Crp1p is subject to efficient proteolysis at one specific site. Cleavage leads to an N-terminal subpeptide of approximately 160 amino acid residues that is capable of binding specifically X-DNA with an estimated dissociation constant (K(d)) of 800nM, and a C-terminal subpeptide of approximately 305 residues without intrinsic X-DNA-binding activity. The N-terminal subpeptide is of a size similarly to that of the fragments identified in yeast, suggesting that the same cleavage process occurs in the yeast and the E.coli background. This makes the action of a site-specific protease unlikely and favours the possibility of an autoproteolytic activity of Crp1p. The DNA-binding domain of Crp1p was mapped to positions 120-141. This domain can act autonomously as an X-DNA-binding peptide and provides a new, lysine-rich DNA-binding domain different from those of known cruciform DNA-binding proteins (CBPs). As reported earlier for several other CBPs, Crp1p exerts an enhancing effect on the cleavage of X-DNA by endonuclease VII from bacteriophage T4.     

Molecular cloning and analysis of the CRY1 gene: a yeast ribosomal protein gene.

Using cloned DNA from the vicinity of the yeast mating type locus (MAT) as a probe, the wild type allele of the cryptopleurine resistance gene CRY1 has been isolated by the technique of chromosome walking and has been shown to be identical to the gene for ribosomal protein 59. A recessive cryR1 allele has also been cloned, using the integration excision method. The genetic distance from MAT to CRY1 is 2.2 cM, while the physical distance is 21 kb, giving a ratio of about 10 kb/cM for this interval. The phenotypic expression of both plasmid borne alleles of the gene can be detected in vivo. The use of this gene as a hybridization probe to examine RNA processing defects in the rna 2, rna 3, rna 4, rna 8, and rna 11 mutants is also discussed.     

Telomere binding of the Rap1 protein is required for meiosis in fission yeast.

Telomeres are essential for chromosome integrity, protecting the ends of eukaryotic linear chromosomes during cell proliferation. Telomeres also function in meiosis; a characteristic clustering of telomeres beneath the nuclear membrane is observed during meiotic prophase in many organisms from yeasts to plants and humans, and the role of the telomeres in meiotic pairing and the recombination of homologous chromosomes has been demonstrated in the fission yeast Schizosaccharomyces pombe and in the budding yeast Saccharomyces cerevisiae. Here we report that S. pombe Rap1 is a telomeric protein essential for meiosis. While Rap1 is conserved in budding yeast and humans, schemes for telomere binding vary among species: human RAP1 binds to the telomere through interaction with the telomere binding protein TRF2; S. cerevisiae Rap1, however, binds telomeric DNA directly, and no orthologs of TRF proteins have been identified in this organism. In S. pombe, unlike in S. cerevisiae, an ortholog of human TRF has been identified. This ortholog, Taz1, binds directly to telomere repeats [18] and is necessary for telomere clustering in meiotic prophase. Our results demonstrate that S. pombe Rap1 binds to telomeres through interaction with Taz1, similar to human Rap1-TRF2, and that Taz1-mediated telomere localization of Rap1 is necessary for telomere clustering and for the successful completion of meiosis. Moreover, in taz1-disrupted cells, molecular fusion of Rap1 with the Taz1 DNA binding domain recovers telomere clustering and largely complements defects in meiosis, indicating that telomere localization of Rap1 is a key requirement for meiosis.     

A Drosophila ribosomal protein gene is located near repeated sequences including rDNA sequences.

We have isolated a cloned segment of Drosophila genomic DNA containing a ribosomal protein gene. Hybridization analysis of the DNA in this clone indicates a complex organization of repeated elements within this cloned segment. At least one of these repeated elements is homologous to regions of rDNA. Restriction analysis of the clone shows that some of the repeated elements are present as tandem duplications and in scattered locations within the cloned DNA segment. There are also three non-ribosomal protein genes contained in this clone, each of which is expressed along with the ribosomal protein gene into RNA species present in Drosophila embryos.