Directional telomeric silencing and lack of canonical B1 elements in two silencer Autonomously Replicating Sequences in S. cerevisiae.

BACKGROUND: Autonomously Replicating Sequences (ARS) in S. cerevisiae serve as origins of DNA replication or as components of cis-acting silencers, which impose positional repression at the mating type loci and at the telomeres. Both types of ARS can act as replicators or silencers, however it is not clear how these quite diverse functions are executed. It is believed that all ARS contain a core module of an essential ARS Consensus Sequence (ACS) and a non-essential B1 element. RESULTS: We have tested how the B1 elements contribute to the silencer and replicator function of ARS. We report that the ACS-B1 orientation of ARS has a profound effect on the levels of gene silencing at telomeres. We also report that the destruction of the canonical B1 elements in two silencer ARS (ARS317 and ARS319) has no effect on their silencer and replicator activity. CONCLUSIONS: The observed orientation effects on gene silencing suggest that ARSs can act as both proto-silencers and as insulator elements. In addition, the lack of B1 suggests that the ACS-B1 module could be different in silencer and replicator ARS.

Oligofluorenes as polymeric model compounds for providing insight into the triplets of ketone and ketylimine derivatives.

A series of oligofluorenes ranging between one and three repeating units were prepared as structurally well-defined representative models of polyfluorenes. The photophysics of the oligofluorene models were investigated both by laser flash photolysis and steady-state fluorescence. The effects of the ketone and ketylimine functional groups in the 9-position on the photophysical properties, notably the triplet quantum yield (Φ(TT)) by intersystem crossing and the absolute fluorescence quantum yields (Φ(fl)), were investigated. The singlet depletion method was used to determine both the Φ(TT) and molar absorption coefficients of the observed triplets (ε(TT)). Meanwhile, the absolute Φ(fl) were determined using an integrating sphere. It was found that both the ketone and ketylimine substituents and the degree of oligomerization contributed to quenching the oligofluorene fluorescence. For example, the Φ(fl) was quenched 5-fold with the ketylimine and ketone substituents for the bifluorenyl derivatives compared to their corresponding 9,9-dihexyl bifluorenyl counterparts. Meanwhile, the Φ(fl) quenching increased 14 times with the trifluorenyl ketone and ketylimine derivatives. Measured Φ(TT) values ranged between 22 and 43% for the difluorenyl derivatives with ε(TT) on the order of 13 000 cm(-1) M(-1). The Φ(TT) decreased to <10% concomitant with doubling of the ε(TT) when the degree of oligomerization was increased to 3. A new fluorescence emission at 545 nm formed at low temperatures for the ketone and ketylimine oligofluorene derivatives. The emission intensity was dependent on the temperature, and it disappeared at room temperature.

GCN5 is a positive regulator of origins of DNA replication in Saccharomyces cerevisiae.

GCN5 encodes one of the non-essential Histone Acetyl Transferases in Saccharomyces cerevisiae. Extensive evidence has indicated that GCN5 is a key regulator of gene expression and could also be involved in transcriptional elongation, DNA repair and centromere maintenance. Here we show that the deletion of GCN5 decreases the stability of mini-chromosomes; that the tethering of Gcn5p to a crippled origin of replication stimulates its activity; that high dosage of GCN5 suppresses conditional phenotypes caused by mutant alleles of bona fide replication factors, orc2-1, orc5-1 and mcm5-461. Furthermore, Gcn5p physically associates with origins of DNA replication, while its deletion leads to localized condensation of chromatin at origins. Finally, Deltagcn5 cells display a deficiency in the assembly of pre-replicative complexes. We propose that GCN5 acts as a positive regulator of DNA replication by counteracting the inhibitory effect of Histone Deacetylases.

Identification and biochemical analysis of a mitochondrial endonuclease of Podospora anserina related to curved-DNA binding proteins.

We purified and characterized previously from Podospora anserina mitochondria an endonuclease, active on single-stranded, double-stranded and flap DNA, with RNAse H activity, named P49 according to the major 49 kDa band observed on SDS-PAGE. Edman sequencing allowed us to identify the corresponding gene called nuc49. Here we report the properties of the (His)-tagged NUC49 protein expressed in E. coli. We show that this protein does exhibit an endonuclease activity on plasmid DNA, circular recessed and flap M13 substrate with short protruding single strand. However, in contrast to the mt endonuclease purified fraction it does not present RNase H activity and does not cleave linear flap substrate. The activity differences between the protein expressed in E. coli and the mitochondrial endonuclease fraction previously described are discussed. NUC49 presents a strong homology with the S. pombe CDB4 curved DNA binding protein which belongs to a large family including the human cell cycle protein PA2G4 and is able to bind curved DNA. The results constitute the first description of a mitochondrial endonuclease activity associated to this family of proliferation associated homologous proteins. The function of this endonuclease either in recombination, repair or mt DNA rearrangements remains to be determined.

Stimulation of a mitochondrial endo-exonuclease from Podospora anserina by PCNA.

In Podospora anserina we have described the purification of an endo-exonuclease (Biochim. Biophys. Acta 1574 (1) (2002) 72). Given the description of several nucleases addressed to the mitochondria and known to interact with the PCNA, we sought a possible effect of PCNA on the mt nuclease. A significant stimulation of the nuclease activity with PCNA was observed with double-stranded and flap structure DNA. Immuno-Western blotting experiments realized with monoclonal antibodies raised against the PCNA specifically revealed the presence of a single band of 30 kDa in the mitochondria from the filamentous fungus and yeast. A potential PCNA binding motif was found in the sequences of several mt nucleases and mt proteins involved in the maintenance of the mt DNA with respect to the consensus described by Warbrick. The hypothetical role of the PCNA as a potential regulator of the repair/recombination processes in the maintenance of the mt genome is discussed.

Purification and characterization of an endo-exonuclease from Podospora anserina mitochondria.

The senescence phenotype of Podospora anserina wild-type strains depends on mitochondrial (mt) genome stability. Characterization of activities implicated in the maintenance of the mt DNA is therefore essential for a better understanding of these degenerative processes. To address this question we looked for a nuclease activity in this fungal mitochondria. Here we describe the purification of an endo-exonuclease active on single-stranded, double-stranded and flap DNA. The Podospora nuclease also possesses an RNase H activity. Gel filtration chromatography showed a native molecular mass of 90 kDa for the P. anserina enzyme. The highly purified fraction shows a single polypeptide chain of 49 kDa on SDS-PAGE, indicating that the Podospora enzyme is probably active as a dimer. Purification and sequencing of the endolysine digestion peptides of the Podospora mt nuclease suggested that this enzyme could belong to the 5' structure-specific endo-exonuclease family. The possible involvement of this nuclease in mt DNA recombination during the senescence process is evoked.