FLP-mediated conditional loss of an essential gene to facilitate complementation assays

Ganesan, Savita

12 1900

Commonly, when it is desirable to replace an essential gene with an allelic series of mutated genes, or genes with altered expression patterns, the complementing constructs are introduced into heterozygous plants, followed by the selection of homozygous null segregants. To overcome this laborious and time-consuming step, the newly developed two-component system utilizes a site-specific recombinase to excise a wild-type copy of the gene of interest from transformed tissues. In the first component (the first vector), a wild-type version of the gene is placed between target sequences recognized by FLP recombinase from the yeast 2 μm plasmid. This construct is transformed into a plant heterozygous for a null mutation at the endogenous locus, and progeny plants carrying the excisable complementing gene and segregating homozygous knockout at the endogenous locus are selected. The second component (the second vector) carries the experimental gene along with the FLP gene. When this construct is introduced, FLP recombinase excises the complementing gene, leaving the experimental gene as the only functional copy. The FLP gene is driven by an egg apparatus specific enhancer (EASE) to ensure excision of the complementing cDNA in the egg cell and zygote following floral-dip transformation. The utility of this system is being tested using various experimental derivatives of the essential sucrose-proton symporter, AtSUC2, which is required for photoassimilate transport.

FLP/FRT recombination

complementation assay

ATSUC2

Gene targeting.

Genetic engineering.

Complementation (Genetics)

Genetic recombination.

Deletion Analysis of the Sinorhizobium meliloti Genome

Milunovic, Branislava

10 1900

<p>The <em>Sinorhizobium meliloti</em> genome consists of 6204 predicted protein-coding regions of which approximately 2000 are proteins of unknown function (PUFs). To identify functions of <em>S. meliloti</em> PUFs, we employed the FRT/Flp recombination system to delete large gene clusters and then screened for phenotypes. Large-scale deletions have been mainly used to define minimal gene sets that contain only those genes that are essential and sufficient to sustain a functioning cell. To adapt FRT/Flp for use in <em>S. meliloti</em>, we used an already constructed pTH1522-derived integration gene library of the <em>S. meliloti</em> genome (pTH1522 carries a single FRT site). A second FRT site was inserted at defined locations in the genome through integration of a second plasmid (pTH1937) that also carries a single FRT site. Here we outline how this Flp/FRT system was used to delete defined regions and hence generate multiple gene knock-out mutants. This system was used to delete 32 and 56 defined regions from the 1340 Kb pSymA and 1678 Kb pSymB megaplasmid, respectively. The structures of the resulting megaplasmid deletion mutants were confirmed by PCR analysis. Carbohydrate and nitrogen utilization phenotypes were associated with the deletion of specific regions. Deleting large, regions of the genome helped us to identify phenotypes such as inability to grow on minimal media with fucose, maltotriose, maltitol, trehalose, palatinose, lactulose and galactosamine as sole carbon source. For several FRT-flanked regions, few or no recombinants were recovered which suggested the presence of essential genes. Through this strategy, two essential genes <em>tRNA^arg </em>and<em> engA</em> located on the pSymB and three toxin/antitoxin-like systems, <em>sma0471</em>/<em>sma0473</em>, <em>sma2105</em> and <em>sma2230</em>/<em>sma2231</em> on pSymA megaplasmid were identified.</p> / Doctor of Philosophy (PhD)

Sinorhizobium meliloti

Flp/FRT recombination system

megaplasmids

essential genes

toxin antitoxin systems

Molecular genetics

Molecular genetics