A smaller PCR amplicon which is not specific to the ags1::T-DNA template was detected in all reactions derived from the random insertion mutant pool. Nested PCR to reduce false-positives To discriminate between true- and false-positive PCR products, we employed a secondary PCR reaction using a set of nested primers. Nested primers
that do not overlap with the primary PCR primers were designed for both the T-DNA anchor and the AGS1 gene. Primary PCR reactions in which OSU4 represented 1/200th or 1/800th of the population were used as templates after 1:1000, 1:10,000, and 1:100,000 dilution in H2O. As shown in Figure 1C, this process eliminated the false-positive band observed in the primary PCR reactions. The ags1::T-DNA specific amplicon Temsirolimus could be detected after either 1:1000 or 1:10,000
dilution of the primary PCR reaction. No ags1::T-DNA amplicon was produced when OSU4 was absent in the primary reaction template DNA. These data demonstrate that PCR can be an efficient screening technique to probe mutant pools for a clone in which a T-DNA element has inserted into a target gene. We selected a target pool size of approximately 200 insertion mutants as a balance between increased throughput afforded by larger pools but easier subdivision of smaller pools into individual clones to recover the detected mutant strain (see below). Establishment of a bank of insertion mutants Optimization PIK3C2G of freezing conditions As the generation of T-DNA insertion mutants in Histoplasma INCB024360 price is not trivial, establishment of a frozen bank of insertion mutants would facilitate future screens without having to produce new mutant pools as additional target genes are identified. Maintaining the mutant representation in the pool after freezing necessitates efficient recovery of viable cells following thawing. To maximize the recovery of cells after freezing we examined two parameters:
the cryoprotectant used and the method of freezing. Glycerol- or DMSO-containing solutions are used for freezing eukaryotic cells as these chemicals reduce membrane-damaging ice crystal formation. We also tested whether slowing the freezing rate using an insulated container also improved recovery from frozen stocks. Histoplasma WU15 yeast cells were frozen and stored at -80°C for 7 days or 9 weeks to determine the short and long term storage recovery rates, respectively. Recovered cfu counts were compared to those before freezing. With glycerol as the cryoprotectant, slowing the freezing rate dramatically improved recovery of viable yeast (Figure 2A), probably resulting from the increased time to allow for penetration of glycerol into cells during cooling. DMSO was a superior cryoprotectant than glycerol for Histoplasma yeast when present at concentrations from 4% to 10% (Figure 2B).