DNA breakage is intimately associated with meiotic recombination in the fission yeast Schizosaccharomyces pombe. Sites of prominent DNA breakage were found approximately 25 to approximately 200 kb apart in the genomic regions surveyed. We examined in detail a 501 kb region of chromosome I and found six sites, or tight clusters of sites, at which approximately 2%-11% of the DNA accumulated breaks in a rad50S mutant. In contrast to the discrete, widely spaced distribution of prominent break sites, recombination in this region was more uniformly distributed (0.7-1.6 cM/10 kb) whether the genetic interval tested contained no, one, or more such sites. We infer that although recombination depends upon DNA breakage, recombination often occurs remote from these sites (tens of kilobases away); we discuss mechanisms by which this may occur.
The ade6-M26 allele of Schizosaccharomyces pombe creates a well-defined meiotic recombination hot spot that requires a specific sequence, 5'-ATGACGT-3', and the Atf1*Pcr1 transcription factor for activity. We find that M26 stimulates the formation of meiosis-specific double-strand DNA breaks at multiple sites surrounding M26. Like hot spot activity, breakage requires the M26 heptamer, Pcr1, and the general recombination factor Rec12. When the M26 heptamer is moved to new positions within ade6, new break sites are observed spanning approximately 0.5-2 kb around the moved heptamer. Break frequency is strongly correlated with recombination frequency for these alleles. The occurrence of breaks at M26 suggests mechanistic similarities to hot spots in the distantly related yeast Saccharomyces cerevisiae.
A novel panfungal PCR assay which detects the small-subunit rRNA gene sequence of the two major fungal organism groups was used to test whole-blood specimens obtained from a series of blood or bone marrow transplant recipients. The 580-bp PCR product was identified after amplification by panfungal primers and hybridization to a 245-bp digoxigenin-labeled probe. The lower limit of detection of the assay was approximately four organisms per milliliter of blood. Multiple whole-blood specimens from five patients without fungal infection or colonization had negative PCR results. Specimens from 11 infected patients had positive PCR results. Blood from three patients with pulmonary aspergillosis had positive PCR results: one patient’s blood specimen obtained in the week prior to the diagnosis of infection by a positive bronchoalveolar lavage fluid culture result was positive by PCR, and blood specimens obtained from two patients 1 to 2 days after lung biopsy and which were sterile by culture were positive by PCR. The blood of four patients with candidemia, three patients with mixed fungal infections, and one patient with fusariosis also had positive PCR signals. The panfungal PCR assay can detect multiple fungal genera and may be used as an adjunct to conventional methods for the detection of fungal infection or for describing the natural history of fungal infection. Further studies are needed to define the sensitivity and specificity of this assay for the diagnosis of fungal infection prior to the existence of other clinical or laboratory indications of invasive fungal infection.
Filamentous fungi have a sturdy cell wall which is resistant to the usual DNA extraction procedures. We determined the DNA extraction procedure with the greatest yield of high quality fungal DNA and the least predilection for cross-contamination of equipment between specimens. Each of six extraction methods was performed using Aspergillus fumigatus hyphae. The six methods were: (1) glass bead pulverization with vortexing; (2) grinding with mortar and pestle followed by glass bead pulverization; (3) glass bead pulverization using 1% hydroxyacetyl trimethyl ammonium bromide (CTAB) buffer in a water bath sonicator; (4) water bath sonication in CTAB buffer; (5) grinding followed by incubation with CTAB; and (6) lyticase enzymatic cell lysis. Genomic DNA yields were measured by spectrophotometry and by visual reading of 2% agarose gels, with shearing assessed by the migration of the DNA on the gel. Genomic fungal DNA yields were highest for Method 1, followed by Methods 5 approximately = to 2 >3 approximately = to 4 approximately = to 6. Methods 2 and 5, both of which involved grinding with mortar and pestle, led to shearing of the genomic DNA in one of two trials each. We conclude that the use of glass beads with extended vortexing is optimal for extraction of microgramme amounts of DNA from filamentous fungal cultures.
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