Miroslava Slaninová

The alga Chlamydomonas reinhardtii UVS11 gene is responsible for cell division delay and temporal decrease in histone H1 kinase activity caused by UV irradiation

The aim of the present work was to study the possible role of the UVS11 gene of the alga Chlamydomonas reinhardtii, in regulation of the cell cycle. To characterize the defect of a uvs11 mutant in respect to DNA damage-dependent cell cycle arrest, we examined first the influence of the tubulin-destabilizing drug methyl benzimidazole-2-yl-carbamate (MBC) on inhibition of mitosis in response to UV 254nm. Then the growth and reproductive processes and activity of cyclin-dependent kinases (CDK)-like kinases during the cell cycle of C. reinhardtii were investigated. In both, the wild type and the uvs11 mutant strain were compared under standard conditions and after DNA damage caused by UV 254nm. We assume the green alga C. reinhardtii possesses control mechanisms allowing to stop the cell cycle progression before mitosis in response to DNA damage. The results indicate that the uvs11 mutant is not able to stop the cell cycle after UV irradiation. We suggest that a product of the UVS11 gene affects cell response to DNA damage and influences a decrease in histone H1 kinase activity.

Effect of bacterial recA expression on DNA repair in the rad51 and rad52 mutants of Saccharomyces cerevisiae

Molecular and functional homology between yeast proteins pRad51 and pRad52 and Escherichia coli pRecA involved in recombinational DNA repair led us to investigate possible effects of recA gene expression on DNA repair in rad51 and rad52 mutants of Saccharomyces cerevisiae. The mutant cells were subjected to one of the following treatments: preincubation with 8-methoxypsoralen and subsequent irradiation with 360-nm ultraviolet (UVA) (8-MOP + UVA), irradiation with 254-nm UV light or treatment with methyl methane sulfonate (MMS). While recA expression did not repair lethal DNA lesions in mutant rad51, it was able to partially restore resistance to 8-MOP + UVA and MMS in rad52. Expression of recA could not complement the sensitivity of rad51rad52 double mutants, indicating that pRad51 may be essential for the repair-stimulating activity of pRecA in the rad52 mutant. Spontaneous mutagenesis was increased, and 8-MOP-photoinduced mutagenesis was decreased by the presence of pRecA in rad52, whereas pRecA decreased UV-induced mutagenesis in rad51. Thus, pRecA may function in yeast DNA repair either as a member of a protein complex or as an individual protein that binds to mutagen-damaged DNA.

Characterization of DNA Repair Deficient Strains of Chlamydomonas reinhardtii Generated by Insertional Mutagenesis

While the mechanisms governing DNA damage response and repair are fundamentally conserved, cross-kingdom comparisons indicate that they differ in many aspects due to differences in life-styles and developmental strategies. In photosynthetic organisms these differences have not been fully explored because gene-discovery approaches are mainly based on homology searches with known DDR/DNA repair proteins. Here we performed a forward genetic screen in the green algae Chlamydomonas reinhardtii to identify genes deficient in DDR/DNA repair. We isolated five insertional mutants that were sensitive to various genotoxic insults and two of them exhibited altered efficiency of transgene integration. To identify genomic regions disrupted in these mutants, we established a novel adaptor-ligation strategy for the efficient recovery of the insertion flanking sites. Four mutants harbored deletions that involved known DNA repair factors, DNA Pol zeta, DNA Pol theta, SAE2/COM1, and two neighbouring genes encoding ERCC1 and RAD17. Deletion in the last mutant spanned two Chlamydomonas-specific genes with unknown function, demonstrating the utility of this approach for discovering novel factors involved in genome maintenance.

Is it possible to improve homologous recombination in Chlamydomonas reinhardtii

Targeted modification of the genome has long been an aim of many geneticists and biotechnologists. Gene targeting is a main molecular tool to examine biological effects of genes in a controlled environment. Effective gene targeting depends on the frequency of homologous recombination that is indispensable for the insertion of foreign DNA into a specific sequence of the genome. The main problem associated with the development of an optimal procedure for gene targeting in a particular organism is the variability of homologous recombination (HR) in different species. Chlamydomonas reinhardtii is an attractive model system for the study of many cellular processes and is also an interesting object for the biotechnology industry. In spite of many advantages of this model system, C. reinhardtii does not readily express heterologous genes and does not allow targeted integration of foreign DNA into its genome easily. This paper compares data obtained from several different experiments designed for improving gene targeting in different organisms and reviews the suitability of particular techniques in C. reinhardtii cells.

Studies on Recombination Processes in two Chlamydomonas reinhardtii Endogenous Genes, NIT1 and ARG7

Integration of exogenous DNA in the unicellular green alga Chlamydomonas reinhardtii is principally carried out by mechanisms involving non-homologous recombination (NHR), rather than homologous recombination (HR). Homologous recombination is, however, the mechanism of choice when it comes to gene targeting. Unfortunately, attempts to establish this method in Chlamydomonas have had limited success. In this study we compared two endogenous genes, NIT1 and ARG7, and their HR/NHR ratios when different types of fragments were used as donors of homologous sequences. Transformation of the auxotrophic strain containing the inactivating point mutation arg7-8 with nonfunctional ARG7 gene fragments overlapping this mutation showed increased HR efficiencies when linearized plasmids were used. Efficiency went down rapidly with decreasing length of ARG7 homology. After identification of the inactivating 6726(G→A) point mutation in nit1-305 strains, an analogous set of experiments was performed. In the case of NIT1, overall efficiency of recombination was 10 to 100 fold lower than with ARG7. In order to better demonstrate HR we introduced three silent mutations close to the position of the point mutations in our transforming plasmids. Sequencing of transformants indicated homologous recombination over a short interval.

Expression ofEscherichia coli recA andada genes inSaccharomyces cerevisiœ using a vector with geneticin resistance

Construction ofE. coli-yeast shuttle plasmids containing theneo selection gene is described. The protein-coding regions of theE. coli ada orrecA genes under the control of theADH1 promoter and terminator were ligated into theSphI unique site of pNF2 to produce pMSada and pMSrecA, respectively. The plasmids were used for transformation of the haploid and diploidpso4-1 strains ofS. cerevisiœ and their corresponding wild types. Transformants were obtained by selection for geneticin (G418) resistance. Crude protein samples were extracted from the individual transformants. Both the RecA and Ada proteins were present in all strains containing therecA andada genes on plasmids, respectively. Thus the geneticin selection system was successfully used for the preparation of model, yeast strains.