Characterization of pneumocystis major surface glycoprotein gene (msg) promoter activity in Saccharomyces cerevisiae.

Major surface glycoprotein (Msg), the most abundant cell surface protein of Pneumocystis, plays an important role in the interaction of this opportunistic pathogen with host cells, and its potential for antigenic variation may facilitate evasion of host immune responses. In the present study, we have identified and characterized the promoter region of msg in 3 species of Pneumocystis: P. carinii, P. jirovecii, and P. murina. Because Pneumocystis cannot be cultured, promoter activity was measured in Saccharomyces cerevisiae, a related fungus, using a yeast vector modified to utilize the gene coding for Renilla luciferase as a reporter gene. The 5'-flanking sequences of msg from all three Pneumocystis species showed considerable promoter activity, with increases in luciferase activity up to 15- to 44-fold above baseline. Progressive deletions helped define an ∼13-bp sequence in each Pneumocystis species that appears to be critical for promoter activity. Electrophoretic mobility shift analysis using P. carinii-specific msg promoter sequences demonstrated binding of nuclear proteins of S. cerevisiae. The 144-bp 5'-flanking region of P. murina msg showed 72% identity to that of P. carinii. The 5'-flanking region of P. jirovecii msg showed 58 and 61% identity to those of P. murina and P. carinii, respectively. The msg promoter is a good candidate for inclusion in a construct designed for genetic manipulation of Pneumocystis species.

Characterization of the meiosis-specific recombinase Dmc1 of pneumocystis.

The life cycle of Pneumocystis, which causes life-threatening pneumonia in immunosuppressed patients, remains poorly defined. In the present study, we have identified and characterized an orthologue of dmc1, a gene specific for meiotic recombination in yeast, in 3 species of Pneumocystis. dmc1 is a single-copy gene that is transcribed as ∼1.2-kb messenger RNA, which encodes a protein of 336-337 amino acids. Pneumocystis Dmc1 was 61%-70% identical to those from yeast. Confocal microscopy results indicated that the expression of Dmc1 is primarily confined to the cyst form of Pneumocystis. By sequence analysis of 2 single-copy regions of the human Pneumocystis jirovecii genome, we can infer multiple recombination events, which are consistent with meiotic recombination in this primarily haploid organism. Taken together, these studies support the occurrence of a sexual phase in the life cycle of Pneumocystis.

Genome-wide mapping of meiotic DNA double-strand breaks in Saccharomyces cerevisiae.

DNA double-strand breaks (DSBs) initiate meiotic recombination in eukaryotes. We describe two strategies that use microarrays to determine the genome-wide distribution of meiotic DSBs in the yeast Saccharomyces cerevisiae. The first is a chromatin immunoprecipitation (ChIP) approach that targets the Spo11 protein, which remains covalently attached to DSB ends in certain mutant backgrounds. The second approach involves BND cellulose enrichment of the single-strand DNA (ssDNA) recombination intermediate formed by end-resection at DSB sites following Spo11 removal.

Techniques for gamma-H2AX detection.

When a double-strand break (DSB) forms in DNA, many molecules of histone H2AX present in the chromatin flanking the break site are rapidly phosphorylated. The phosphorylated derivative of H2AX is named gamma-H2AX, and the phosphorylation site is a conserved serine four residues from the C-terminus, 139 in mammals and 129 in budding yeast. An antibody to gamma-H2AX reveals that the molecules form a gamma-focus at the DSB site. The gamma-focus increases in size rapidly for 10-30 min after formation, and remains until the break is repaired. Studies have revealed that small numbers of gamma-foci are present in cells even without the purposeful introduction of DNA DSBs. These cryptogenic foci increase in number during senescence in culture and aging in mice. This chapter presents techniques for revealing gamma-H2AX foci in cultured cells, in metaphase spreads from cultured cells, in tissues, and in yeast.

DNA damage response pathway uses histone modification to assemble a double-strand break-specific cohesin domain.

The postreplicative repair of double-strand breaks (DSBs) is thought to require sister chromatid cohesion, provided by the cohesin complex along the chromosome arms. A further specialized role for cohesin in DSB repair is suggested by its de novo recruitment to regions of DNA damage in mammals. Here, we show in budding yeast that a single DSB induces the formation of a approximately 100 kb cohesin domain around the lesion. Our analyses suggest that the primary DNA damage checkpoint kinases Mec1p and Tel1p phosphorylate histone H2AX to generate a large domain, which is permissive for cohesin binding. Cohesin binding to the phospho-H2AX domain is enabled by Mre11p, a component of a critical repair complex, and Scc2p, a component of the cohesin loading machinery that is necessary for sister chromatid cohesion. We also provide evidence that the DSB-induced cohesin domain functions in postreplicative repair.

Distribution and dynamics of chromatin modification induced by a defined DNA double-strand break.

BACKGROUND: In response to DNA double-strand breaks (DSBs), eukaryotic cells rapidly phosphorylate histone H2A isoform H2AX at a C-terminal serine (to form gamma-H2AX) and accumulate repair proteins at or near DSBs. To date, these events have been defined primarily at the resolution of light microscopes, and the relationship between gamma-H2AX formation and repair protein recruitment remains to be defined. RESULTS: We report here the first molecular-level characterization of regional chromatin changes that accompany a DSB formed by the HO endonuclease in Saccharomyces cerevisiae. Break induction provoked rapid gamma-H2AX formation and equally rapid recruitment of the Mre11 repair protein. gamma-H2AX formation was efficiently promoted by both Tel1p and Mec1p, the yeast ATM and ATR homologs; in G1-arrested cells, most gamma-H2AX formation was dependent on Tel1 and Mre11. gamma-H2AX formed in a large (ca. 50 kb) region surrounding the DSB. Remarkably, very little gamma-H2AX could be detected in chromatin within 1-2 kb of the break. In contrast, this region contains almost all the Mre11p and other repair proteins that bind as a result of the break. CONCLUSIONS: Both Mec1p and Tel1p can respond to a DSB, with distinct roles for these checkpoint kinases at different phases of the cell cycle. Part of this response involves histone phosphorylation over large chromosomal domains; however, the distinct distributions of gamma-H2AX and repair proteins near DSBs indicate that localization of repair proteins to breaks is not likely to be the main function of this histone modification.