The velvet family of fungal regulators contains a DNA-binding domain structurally similar to NF-κB.

Morphological development of fungi and their combined production of secondary metabolites are both acting in defence and protection. These processes are mainly coordinated by velvet regulators, which contain a yet functionally and structurally uncharacterized velvet domain. Here we demonstrate that the velvet domain of VosA is a novel DNA-binding motif that specifically recognizes an 11-nucleotide consensus sequence consisting of two motifs in the promoters of key developmental regulatory genes. The crystal structure analysis of the VosA velvet domain revealed an unforeseen structural similarity with the Rel homology domain (RHD) of the mammalian transcription factor NF-κB. Based on this structural similarity several conserved amino acid residues present in all velvet domains have been identified and shown to be essential for the DNA binding ability of VosA. The velvet domain is also involved in dimer formation as seen in the solved crystal structures of the VosA homodimer and the VosA-VelB heterodimer. These findings suggest that defence mechanisms of both fungi and animals might be governed by structurally related DNA-binding transcription factors.

Rad26p, a transcription-coupled repair factor, promotes the eviction and prevents the reassociation of histone H2A-H2B dimer during transcriptional elongation in vivo.

We have recently demonstrated the formation of an atypical histone H2A-H2B dimer-enriched chromatin at the coding sequence of the active gene in the absence of Rad26p in vivo. However, the mechanisms for such a surprising observation remain unknown. Here, using a ChIP assay, we demonstrate that Rad26p promotes the eviction of histone H2A-H2B dimer and prevents the reassociation of the dimer with naked DNA in the wake of elongating RNA polymerase II at the coding sequence of the active GAL1 gene. Thus, the absence of Rad26p leads to the generation of an atypical histone H2A-H2B dimer-enriched chromatin at the active coding sequence in vivo.

DNA-damage response in the basidiomycete fungus Ustilago maydis relies in a sole Chk1-like kinase.

Chk1 is a protein kinase that acts as a key signal transducer within the complex network responsible of the cellular response to different DNA damages. It is a conserved element along the eukaryotic kingdom, together with a second checkpoint kinase, called Chk2/Rad53. In fact, all organisms studied so far carried at least one copy of each kind of checkpoint kinase. Since the relative contribution to the DNA-damage response of each type of kinase varies from one organism to other, the current view about the roles of Chk1 and Chk2/Rad53 during DNA-damage response is one of mutual complementation and intimate cooperation. However, in this work it is reported that Ustilago maydis - a phytopathogenic fungus exhibiting extreme resistance to UV and ionizing radiation - have a single kinase belonging to the Chk1 family but strikingly no kinases related to Chk2/Rad53 family are apparent. The U. maydis Chk1 kinase is able to respond to different classes of DNA damages and its activity is required for the cellular adaptation to such damages. As other described components of the Chk1 family of kinases, U. maydis Chk1 is phosphorylated and translocated to nucleus in response to DNA-damage signals. Interestingly subtle differences in this response depending on the kind of DNA damage are apparent, suggesting that in U. maydis the sole Chk1 kinase recapitulates the roles that in other organisms are shared by Chk1 and the Chk2/Rad53 family of protein kinases.

The role of novel genes rrp1(+) and rrp2(+) in the repair of DNA damage in Schizosaccharomyces pombe.

We identified two predicted proteins in Schizosaccharomyces pombe, Rrp1 (SPAC17A2.12) and Rrp2 (SPBC23E6.02) that share 34% and 36% similarity to Saccharomyces cerevisiae Ris1p, respectively. Ris1p is a DNA-dependent ATP-ase involved in gene silencing and DNA repair. Rrp1 and Rrp2 also share similarity with S. cerevisiae Rad5 and S. pombe Rad8, containing SNF2-N, RING finger and Helicase-C domains. To investigate the function of the Rrp proteins, we studied the DNA damage sensitivities and genetic interactions of null mutants with known DNA repair mutants. Single Deltarrp1 and Deltarrp2 mutants were not sensitive to CPT, 4NQO, CDPP, MMS, HU, UV or IR. The double mutants Deltarrp1 Deltarhp51 and Deltarrp2 Deltarhp51 plus the triple Deltarrp1 Deltarrp2 Deltarhp51 mutant did not display significant additional sensitivity. However, the double mutants Deltarrp1 Deltarhp57 and Deltarrp2 Deltarhp57 were significantly more sensitive to MMS, CPT, HU and IR than the Deltarhp57 single mutant. The checkpoint response in these strains was functional. In S. pombe, Rhp55/57 acts in parallel with a second mediator complex, Swi5/Sfr1, to facilitate Rhp51-dependent DNA repair. Deltarrp1 Deltasfr1 and Deltarrp2 Deltasfr1 double mutants did not show significant additional sensitivity, suggesting a function for Rrp proteins in the Swi5/Sfr1 pathway of DSB repair. Consistent with this, Deltarrp1 Deltarhp57 and Deltarrp2 Deltarhp57 mutants, but not Deltarrp1 Deltasfr1 or Deltarrp2 Deltasfr1 double mutants, exhibited slow growth and aberrations in cell and nuclear morphology that are typical of Deltarhp51.

Deoxynucleic acids from Cryptococcus neoformans activate myeloid dendritic cells via a TLR9-dependent pathway.

The mechanism of host cell recognition of Cryptococcus neoformans, an opportunistic fungal pathogen in immunocompromised patients, remains poorly understood. In the present study, we asked whether the DNA of this yeast activates mouse bone marrow-derived myeloid dendritic cells (BM-DCs). BM-DCs released IL-12p40 and expressed CD40 upon stimulation with cryptococcal DNA, and the response was abolished by treatment with DNase, but not with RNase. IL-12p40 production and CD40 expression were attenuated by chloroquine, bafilomycin A, and inhibitory oligodeoxynucleotides (ODN) that suppressed the responses caused by CpG-ODN. Activation of BM-DCs by cryptococcal DNA was almost completely abrogated in TLR9 gene-disrupted (TLR9(-/-)) mice and MyD88(-/-) mice, similar to that by CpG-ODN. In addition, upon stimulation with whole yeast cells of acapsular C. neoformans, TLR9(-/-) BM-DCs produced a lower amount of IL-12p40 than those from wild-type mice, and TLR9(-/-) mice were more susceptible to pulmonary infection with this fungal pathogen than wild-type mice, as shown by increased number of live colonies in lungs. Treatment of cryptococcal DNA with methylase resulted in reduced IL-12p40 synthesis by BM-DCs. Furthermore, using a luciferase reporter assay, cryptococcal DNA activated NF-kappaB in HEK293 cells transfected with the TLR9 gene. Finally, confocal microscopy showed colocalization of fluorescence-labeled cryptococcal DNA with CpG-ODN and the findings merged in part with the distribution of TLR9 in BM-DCs. Our results demonstrate that cryptococcal DNA causes activation of BM-DCs in a TLR9-dependent manner and suggest that the CpG motif-containing DNA may contribute to the development of inflammatory responses after infection with C. neoformans.

Identification and characterization of the rlp1+, the novel Rad51 paralog in the fission yeast Schizosaccharomyces pombe.

A new DNA repair gene from fission yeast Schizosaccharomyces pombe rlp1+ (RecA-like protein) has been identified. Rlp1 shows homology to RecA-like proteins, and is the third S. pombe Rad51 paralog besides Rhp55 and Rhp57. The new gene encodes a 363 aa protein with predicted Mr of 41,700 and has NTP-binding motif. The rlp1Delta mutant is sensitive to methyl methanesulfonate (MMS), ionizing radiation (IR), and camptothecin (CPT), although to a lesser extent than the deletion mutants of rhp55+ and rhp51+ genes. In contrast to other recombinational repair mutants, the rlp1Delta mutant does not exhibit sensitivity to UV light and mitomycin C (MMC). Mitotic recombination is moderately reduced in rlp1 mutant. Epistatic analysis of MMS and IR-sensitivity of rlp1Delta mutant indicates that rlp1+ acts in the recombinational pathway of double-strand break (DSB) repair together with rhp51+, rhp55+, and rad22+ genes. Yeast two-hybrid analysis suggests that Rlp1 may interact with Rhp57 protein. We propose that Rlp1 have an accessory role in repair of a subset of DNA damage induced by MMS and IR, and is required for the full extent of DNA recombination and cell survival under condition of a replication fork collapse.

Cell biology. An age of instability.

It is well established that as we age our cancer risk increases dramatically. As Sinclair explains in his Perspective, the link between cancer and aging is now solidified by new work in budding yeast (McMurray and Gottschling). As yeast cells age there is a marked increase in their genetic instability (a hallmark of cancer), which is independent of the mechanism that determines their life-span.

Functional and physical interaction between Sgs1 and Top3 and Sgs1-independent function of Top3 in DNA recombination repair.

A mutant allele of SGS1 of Saccharomyces cerevisiae was identified as a suppressor of the slow-growth phenotype of top3 mutants. We previously reported the involvement of Top3 via the interaction with the N-terminal region of Sgs1 in the complementation of methylmethanesulfonate (MMS) sensitivity and the suppression of hyper recombination of a sgs1 mutant. In this study, we found that several amino acids residues in the N-terminal region of Sgs1 between residues 4 and 33 were responsible for binding to Top3 and essential for complementing the sensitivity to MMS of sgsl cells. Two-hybrid assays suggested that the region of Top3 responsible for the binding to Sgs1 was bipartite, with portion in the N- and C-terminal domains. Although disruption of the SGS1 gene suppressed the semi-lethality of the top3 mutant of strain MR, the sgsl-top3 double mutant grew more slowly and was more sensitive to MMS than the sgsl single mutant, indicating that Top3 plays some role independently of Sgs1. The DNA topoisomerase activity of Top3 was required for the Top3 function to repair DNA damages induced by MMS, as shown by the fact that the TOP3 gene carrying a mutation (Phe for Tyr) at the amino acid residue essential for its activity (residue 356) failed to restore the MMS sensitivity of sgs1-top3 to the level of that of the sgs1 single mutant. Epistatic analysis using the sgs1-top3 double mutant, rad52 mutant and sgs1-top3-rad52 triple mutant indicated that TOP3 belongs to the RAD52 recombinational repair pathway.

Repair of DNA loops involves DNA-mismatch and nucleotide-excision repair proteins.

A number of enzymes recognize and repair DNA lesions. The DNA-mismatch repair system corrects base-base mismatches and small loops, whereas the nucleotide-excision repair system removes pyrimidine dimers and other helix-distorting lesions. DNA molecules with mismatches or loops can arise as a consequence of heteroduplex formation during meiotic recombination. In the yeast Saccharomyces cerevisiae, repair of mismatches results in gene conversion or restoration, and failure to repair the mismatch results in post-meiotic segregation (PMS). The ratio of gene-conversion to PMS events reflects the efficiency of DNA repair. By examining the PMS patterns in yeast strains heterozygous for a mutant allele with a 26-base-pair insertion, we find that the repair of 26-base loops involves Msh2 (a DNA-mismatch repair protein) and Rad1 (a protein required for nucleotide-excision repair).

How the cytoskeleton recognizes and sorts nuclei of opposite mating type during the sexual cycle in filamentous ascomycetes.

In heterothallic filamentous ascomycetes, two nuclei of opposite mating type must recognize one another in a plurinucleate cell to form a pair prior to karyogamy. In pseudohomothallic species, two nuclei of opposite mating type must also pair after meiosis to form a binucleate spore. We have examined the cytoskeletal involvement in nuclear pairings by immunofluorescence and drug disruption, using heterothallic and pseudohomothallic species, as well as species without defined mating type (homothallic). Nuclei of species with defined mating type have spindle pole bodies which react with chromatin stains; those of homothallic species do not. The reactivity is seen only in interphase, not during nuclear divisions; thus, the DNA concerned is nuclear and not organellar. From light and immunofluorescence microscopy, the DNA is located at the nuclear face of the spindle pole body (SPB). We suggest that the DNA-SPB association may be involved in the recognition of self and nonself between nuclei of opposite mating types. Nuclei which cooperate in cell formation during ascus development or sporulation are placed in close proximity by the arrangement of spindles during the division preceding cell formation; after division, each nuclear pair remains linked by intertwined microtubule asters. Nuclear pairs must migrate before binucleate spore formation. Drug disruptions established that actin-myosin interaction was the most important cytoskeletal factor in normal spore production. The ascomycete SPB shows unexpected flexibility in form and location during development. Prior to sporulation the outer plaque shows extensive modification in size and orientation. The modified portion detaches from the nucleus and acts as a cortical microtubule organizing center, while the rest of the spindle pole body remains at the nucleus.

Centromere-dependent binding of yeast minichromosomes to microtubules in vitro.

We present an in vitro assay for yeast centromere function; isolated yeast minichromosomes require a functional centromere to bind to bovine microtubules and sediment with them. Centromere-bovine microtubule complexes form at physiological microtubule concentrations. Two of the three centromere DNA elements, which are necessary for centromere function in vivo, are also necessary for centromeres to bind microtubules in vitro. However, purified centromere DNA alone does not bind to microtubules. These results suggest that microtubule binding must be mediated by the two centromere DNA elements and factors that associate with one or both of them. The percent of centromeres with microtubule-binding activity is 7- to 10-fold higher in lysates made from nocodazole-arrested G2-M cells than from alpha factor G1 cells, suggesting that this centromere activity is regulated during the cell cycle. The potential of this assay for dissecting centromere assembly, function, and regulation is discussed.

The C-terminal part of a gene partially homologous to CDC 25 gene suppresses the cdc25-5 mutation in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, the product of the CDC25 gene is required for progression in the cell division cycle. It is necessary for cAMP production. It has been suggested that the CDC25 gene product acts through Ras proteins. We report the cloning of a DNA fragment from a new gene able to suppress the thermosensitive phenotype of the cdc25-5 mutation. It is unable to suppress the defect of a mutant of the adenylate cyclase gene or of the ras1, ras2ts double mutant. This DNA fragment prevents the drop in cAMP level in cdc25-5 mutant cells shifted to restrictive temperature. The complementing part of this fragment contains a truncated open reading frame (ORF) corresponding to the 3' end of a gene we named SCD25. The 584-amino acid sequence deduced from this ORF shares 45% identity with the 592-aa C-terminal part of the CDC25 ORF which is sufficient for complementation of cdc25 mutations. Some of the common sequences between these two genes are also partially homologous with the amino acid sequence of LTE1, another gene of S. cerevisiae. The capacity of the SCD25 fragment to suppress a cdc25 mutation and its homology to the C-terminal part of the CDC25 led us to propose that the CDC25 and the SCD25 C-terminal fragments each encode a protein domain which is capable in itself to support a similar biochemical function.

Microtubule-associated protein-2 stimulates DNA synthesis catalyzed by the nuclear matrix.

Microtubule-associated protein-2 (MAP-2) isolated from porcine brains stimulated DNA synthesis catalyzed by the nuclear matrix isolated from Physarum polycephalum in the presence of activated DNA as exogenous templates. The degree of the stimulation depended on the amount of the nuclear matrix, but not on that of the template. MAP-2 also stimulated DNA polymerase alpha activity solubilized from nuclei, but not DNA polymerase beta activity. These results suggest that MAP-2 stimulates DNA synthesis by interacting with the putative DNA replication machinery including DNA polymerase alpha bound to the matrix. Similar stimulation occurred in the nuclear matrix isolated from HeLa and rat ascites hepatoma cells, which strongly suggests that MAP-2 is involved in the control of DNA replication in eukaryotic cells.

Flow cytometry reveals a high degree of genomic size variation and mixoploidy in various strains of the acellular slime mold Physarum polycephalum.

High-resolution flow cytometry, using avian erythrocytes as an internal standard, was employed to study constitutive genome size variation of G2-phase nuclei of Physarum polycephalum strains during the macroplasmodial stage of their life cycle. Our results document a previously unknown extent of genome size variation and mixoploidy in this organism. The unimodal diploid strain Tu 291 displayed the largest genome of the strains tested; in contrast, the Colonia strain displayed only half of the Tu 291 G2-phase fluorescence, confirming its haploid nature. An additional strain, derived from a recent cross between Lu897 and Lu898 amoebae, must have arisen by selfing (propagation of only one of the parental genomes to the macroplasmodial stage), since its nuclei display close to the haploid G2-phase DNA content. The observation of a small fraction of corresponding diploid nuclei within the haploid population of this strain, while maintained as microplasmodia, supports the notion that meiosis in haploid strains may require the presence of diploid nuclei. Two of the descendants of the prototype haploid Colonia strain, which were kept for extended periods of time in submerse culture, proved to be near diploid and mixoploid. Polyploidization and subsequent loss of DNA thus seems to contribute to the extremes of genome size variation in Physarum. In addition to unimodal fluorescence distributions, a number of diploid strains displayed bi- and even trimodal distributions within harvests of a single G2-phase macroplasmodium. Analysis of these mixoploid strains by means of gaussian curve-fitting suggests that the smaller genome size differences in Physarum may arise in step-wise diminution of DNA in approximate units of 3-5% of the original Tu 291 genome.