Control of cell division by sex factor F in Escherichia coli. III. Participation of the groES (mopB) gene of the host bacteria

Cell division of F+ bacteria is coupled to DNA replication of the F plasmid. Two plasmid coded genes, letA (ccdA) and letD (ccdB) are indispensable for this coupling. To investigate bacterial genes that participate in this coupling, we attempted to identify the target of the division inhibitor (the letD gene product) of the F plasmid. Two temperature-sensitive growth defective mutants were screened from bacterial mutants that escaped the letD product growth inhibition that occurs in hosts carrying an FletA mutant. Phage P1-mediated transduction and complementation analysis indicated that the temperature-sensitive mutations are located in the groES (mopB) gene, which is essential for the morphogenesis of several bacteriophages and also for growth of the bacteria. The nucleotide sequence of the promoter region of the gene in which the temperature-sensitive mutations had occurred was virtually identical with that of the groES gene of Escherichia coli; furthermore the sequence of the first five amino acid residues and the overall amino acid composition predicted from the nucleotide sequence of the gene match those of the purified GroES protein. The temperature-sensitive mutants did not allow the propagation of phage lambda at 28 degrees C and formed long filamentous structures without septa at 41 degrees C, as is observed in the case of groES mutants. Growth of the two groES mutants tested was not inhibited by the F plasmid with the letA mutation. These observations suggest to us that the morphogenesis gene groES plays a key role in coupling between replication of the F plasmid and cell division of the host cells.     

Titration and conditional knockdown of the prfB gene in Escherichia coli: effects on growth and overproduction of the recombinant mammalian selenoprotein thioredoxin reductase

Release factor 2 (RF2), encoded by the prfB gene in Escherichia coli, catalyzes translational termination at UGA and UAA codons. Termination at UGA competes with selenocysteine (Sec) incorporation at Sec-dedicated UGA codons, and RF2 thereby counteracts expression of selenoproteins. prfB is an essential gene in E. coli and can therefore not be removed in order to increase yield of recombinant selenoproteins. We therefore constructed an E. coli strain with the endogenous chromosomal promoter of prfB replaced with the titratable P(BAD) promoter. Knockdown of prfB expression gave a bacteriostatic effect, while two- to sevenfold overexpression of RF2 resulted in a slightly lowered growth rate in late exponential phase. In a turbidostatic fermentor system the simultaneous impact of prfB knockdown on growth and recombinant selenoprotein expression was subsequently studied, using production of mammalian thioredoxin reductase as model system. This showed that lowering the levels of RF2 correlated directly with increasing Sec incorporation specificity, while also affecting total selenoprotein yield concomitant with a lower growth rate. This study thus demonstrates that expression of prfB can be titrated through targeted exchange of the native promoter with a P(BAD)-promoter and that knockdown of RF2 can result in almost full efficiency of Sec incorporation at the cost of lower total selenoprotein yield.     

Development of a tightly regulatable copper-mediated gene switch system in dermatophytes

Targeted gene deletion is now available for molecular genetic research of dermatophytes, and the physiological roles of several genes have been elucidated. However, this method cannot be applied to essential genes, which can be potential drug targets. To overcome this limitation, we have developed a conditional gene knockdown system using a copper-responsive promoter. The promoter sequence of the copper transporter gene CTR4 (P(CTR4)) and that of the copper efflux pump gene CRP1 (P(CRP1)) derived from Trichophyton rubrum were examined for their response to copper in Arthroderma vanbreuseghemii. P(CTR4) was demonstrated to repress expression of a reporter gene in the presence of copper, while the activity of P(CRP1) was induced by addition of copper. Importantly, P(CTR4) regulated the gene expression more tightly. Furthermore, when P(CTR4) was applied to regulate the expression of the endogenous genes ERG1 and TRP5, their conditional mutants exhibited decreased growth activity under the repressive conditions. These results suggest that the P(CTR4)-based gene regulation system represents a powerful tool for identification and characterization of a broad range of genes, including essential genes, in dermatophytes.     

A novel screening method for cell wall mutants in Aspergillus niger identifies UDP-galactopyranose mutase as an important protein in fungal cell wall biosynthesis

To identify cell wall biosynthetic genes in filamentous fungi and thus potential targets for the discovery of new antifungals, we developed a novel screening method for cell wall mutants. It is based on our earlier observation that the Aspergillus niger agsA gene, which encodes a putative alpha-glucan synthase, is strongly induced in response to cell wall stress. By placing the agsA promoter region in front of a selectable marker, the acetamidase (amdS) gene of A. nidulans, we reasoned that cell wall mutants with a constitutively active cell wall stress response pathway could be identified by selecting mutants for growth on acetamide as the sole nitrogen source. For the genetic screen, a strain was constructed that contained two reporter genes controlled by the same promoter: the metabolic reporter gene PagsA-amdS and PagsA-H2B-GFP, which encodes a GFP-tagged nuclear protein. The primary screen yielded 161 mutants that were subjected to various cell wall-related secondary screens. Four calcofluor white-hypersensitive, osmotic-remediable thermosensitive mutants were selected for complementation analysis. Three mutants were complemented by the same gene, which encoded a protein with high sequence identity with eukaryotic UDP-galactopyranose mutases (UgmA). Our results indicate that galactofuranose formation is important for fungal cell wall biosynthesis and represents an attractive target for the development of antifungals.     

Cryptococcus neoformans virulence gene discovery through insertional mutagenesis

Insertional mutagenesis was applied to Cryptococcus neoformans to identify genes associated with virulence attributes. Using biolistic transformation, we generated 4,300 nourseothricin (NAT)-resistant strains, of which 590 exhibited stable resistance. We focused on mutants with defects in established virulence factors and identified two with reduced growth at 37 degrees C, four with reduced production of the antioxidant pigment melanin, and two with an increased sensitivity to nitric oxide (NO). The NAT insertion and mutant phenotypes were genetically linked in five of eight mutants, and the DNA flanking the insertions was characterized. For the strains with altered growth at 37 degrees C and altered melanin production, mutations were in previously uncharacterized genes, while the two NO-sensitive strains bore insertions in the flavohemoglobin gene FHB1, whose product counters NO stress. Because of the frequent instability of nourseothricin resistance associated with biolistic transformation, Agrobacterium-mediated transformation was tested. This transkingdom DNA delivery approach produced 100% stable nourseothricin-resistant transformants, and three melanin-defective strains were identified from 576 transformants, of which 2 were linked to NAT in segregation analysis. One of these mutants contained a T-DNA insertion in the promoter of the LAC1 (laccase) gene, which encodes a key enzyme required for melanin production, while the second contained an insertion in the promoter of the CLC1 gene, encoding a voltage-gated chloride channel. Clc1 and its homologs are required for ion homeostasis, and in their absence Cu+ transport into the secretory pathway is compromised, depriving laccase and other Cu(+)-dependent proteins of their essential cofactor. The NAT resistance cassette was optimized for cryptococcal codon usage and GC content and was then used to disrupt a mitogen-activated protein kinase gene, a predicted gene, and two putative chloride channel genes to analyze their contributions to fungal physiology. Our findings demonstrate that both insertional mutagenesis methods can be applied to gene identification, but Agrobacterium-mediated transformation is more efficient and generates exclusively stable insertion mutations.     

Use of the arabinose p(bad) promoter for tightly regulated display of proteins on bacteriophage

Phage display is a widely used method to optimize the binding characteristics of protein-ligand interactions. In addition, it has been used to clone genes from genomic and cDNA libraries based on their ligand-binding characteristics. One difficulty often encountered when expressing heterologous proteins by phage display is the toxicity of the protein on the Escherichia coli host. Previous studies have shown that heterologous protein expression can be tightly controlled using plasmids with the P(BAD) promoter of the arabinose operon of E. coli, and the araC gene, which is both a positive and negative regulator of the promoter. We constructed a set of phage display vectors that utilize the P(BAD) promoter to control the expression of proteins on the surface of the M13 bacteriophage. These vectors exhibit tightly controlled expression of proteins on the surface of the phage. In addition, the amount of protein displayed on the phage is modulated by the amount of arabinose present in the growth medium during phage propagation. This may be useful for altering the stringency of binding enrichment during phage display.     

Essential gene identification and drug target prioritization in Aspergillus fumigatus

Aspergillus fumigatus is the most prevalent airborne filamentous fungal pathogen in humans, causing severe and often fatal invasive infections in immunocompromised patients. Currently available antifungal drugs to treat invasive aspergillosis have limited modes of action, and few are safe and effective. To identify and prioritize antifungal drug targets, we have developed a conditional promoter replacement (CPR) strategy using the nitrogen-regulated A. fumigatus NiiA promoter (pNiiA). The gene essentiality for 35 A. fumigatus genes was directly demonstrated by this pNiiA-CPR strategy from a set of 54 genes representing broad biological functions whose orthologs are confirmed to be essential for growth in Candida albicans and Saccharomyces cerevisiae. Extending this approach, we show that the ERG11 gene family (ERG11A and ERG11B) is essential in A. fumigatus despite neither member being essential individually. In addition, we demonstrate the pNiiA-CPR strategy is suitable for in vivo phenotypic analyses, as a number of conditional mutants, including an ERG11 double mutant (erg11BDelta, pNiiA-ERG11A), failed to establish a terminal infection in an immunocompromised mouse model of systemic aspergillosis. Collectively, the pNiiA-CPR strategy enables a rapid and reliable means to directly identify, phenotypically characterize, and facilitate target-based whole cell assays to screen A. fumigatus essential genes for cognate antifungal inhibitors.     

Systematic Reverse Genetics of Transfer-DNA-Tagged Lines of Arabidopsis : Isolation of Mutations in the Cytochrome P450 Gene Superfamily

We have developed an efficient reverse-genetics protocol that uses expedient pooling and hybridization strategies to identify individual transfer-DNA insertion lines from a collection of 6000 independently transformed lines in as few as 36 polymerase chain reactions. We have used this protocol to systematically isolate Arabidopsis lines containing insertional mutations in individual cytochrome P450 genes. In higher plants P450 genes encode enzymes that perform an exceptionally wide range of functions, including the biosynthesis of primary metabolites necessary for normal growth and development, the biosynthesis of secondary products, and the catabolism of xenobiotics. Despite their importance, progress in assigning enzymatic function to individual P450 gene products has been slow. Here we report the isolation of the first 12 such lines, including one (CYP83B1-1) that displays a runt phenotype (small plants with hooked leaves), and three insertions in abundantly expressed genes. The DNAs used in this study are publicly available and can be used to systematically isolate mutants in Arabidopsis.     

The TGV transgenic vectors for single-copy gene expression from the Escherichia coli chromosome

Plasmid-based cloning and expression of genes in Escherichia coli can have several problems: plasmid destabilization; toxicity of gene products; inability to achieve complete repression of gene expression; non-physiological overexpression of the cloned gene; titration of regulatory proteins; and the requirement for antibiotic selection. We describe a simple system for cloning and expression of genes in single copy in the E. coli chromosome, using a non-antibiotic selection for transgene insertion. The transgene is inserted into a vector containing homology to the chromosomal region flanking the attachment site for phage lambda. This vector is then linearized and introduced into a recombination-proficient E. coli strain carrying a temperature-sensitive lambda prophage. Selection for replacement of the prophage with the transgene is performed at high temperature. Once in the chromosome, transgenes can be moved into other lysogenic E. coli strains using standard phage-mediated transduction techniques, selecting against a resident prophage. Additional vector constructs provide an arabinose-inducible promoter (P(BAD)), P(BAD) plus a translation-initiation sequence, and optional chloramphenicol-, tetracycline-, or kanamycin-resistance cassettes. These Transgenic E. coli Vectors (TGV) allow drug-free, single-copy expression of genes from the E. coli chromosome, and are useful for genetic studies of gene function.     

Functional organization of plasmid pKM101.

Tn5 insertion mutants and in vitro-generated deletion mutants of the mutagenesis-enhancing plasmid pKM101 have been used to identify several genetic regions on the pKM101 map. In clockwise order on the pKM101 map are: (i) the bla gene, coding for a beta-lactamase; (ii) the Slo region, responsible for retarding cell growth on minimal medium; (iii) the tra genes, enabling pKM101 to transfer conjugally; (iv) sensitivity to IKe phage (this function[s] maps within the tra region); (v) the muc gene(s), responsible for enhancing ultraviolet light and chemically induced mutagenesis in the cell; and (vi) the Rep region, essential for plasmid replication. The muc gene(s) and the Rep region are contained in a deoxyribonucleic acid region bounded by inverted repeated sequences.