Mechanism of broccoli-mediated verticillium wilt reduction in cauliflower.

ABSTRACT Broccoli is resistant to Verticillium dahliae infection and does not express wilt symptoms. Incorporation of broccoli residues reduces soil populations of V. dahliae. The effects of broccoli residue were tested on the colonization of roots by V. dahliae, plant growth response, and disease incidence of both broccoli and cauliflower in soils with different levels of V. dahliae inoculum and with or without fresh broccoli residue amendments. The three soils included a low-Verticillium soil, a high-Verticillium soil, and a broccoli-rotation soil (soil from a field after two broccoli crops) with an average of 13, 38, and below-detectable levels of microsclerotia per g of soil, respectively. Cauliflower plants in broccoli-amended high-Verticillium soil had significantly (P

Saturation and specificity of the Lon protease of Escherichia coli.

Lon is an ATP-dependent protease of Escherichia coli. The lon mutation has a pleiotropic phenotype: UV sensitivity, mucoidy, deficiency for lysogenization by bacteriophage lambda and P1, and lower efficiency in the degradation of abnormal proteins. All of these phenotypes are correlated with the loss of protease activity. Here we examine the effects of overproduction of one Lon substrate, SulA, and show that it protects two other substrates from degradation. To better understand this protection, we mutagenized the sulA gene and selected for mutants that have partially or totally lost their ability to saturate the Lon protease and thus can no longer protect another substrate. Some of the SulA mutants lost their ability to protect RcsA from degradation but could still protect the O thermosensitive mutant protein (Ots). All of the mutants retained their capacity to induce cell division inhibition. It was also found that deletion of the C-terminal end of SulA affected its activity but did not affect its susceptibility to Lon. We propose that Lon may have more than one specificity for peptide cleavage.

Proteolysis and modulation of the activity of the cell division inhibitor SulA in Escherichia coli lon mutants.

Intracellular accumulation of the inducible cell division inhibitor SulA is modulated by proteases that ensure its degradation, namely, the Lon protease and another ATP-dependent protease(s). Lon- cells are UV sensitive because SulA is stable. We asked whether these ATP-dependent proteases are more active when lon cells are grown at high temperature or in synthetic medium since these conditions decrease the UV sensitivity of lon cells. We found that these growth conditions have no direct effect on Lon-independent degradation of SulA. They may, instead, decrease the SulA-FtsZ interaction.

Mutational analysis of IS10's outside end.

We present the genetic analysis of a large number of mutations in the outside end of insertion sequence IS10. (i) The terminal inverted repeat sequence is probably the primary site of transposase binding. Mutations in this region fall into phenotypic classes which correspond to their map locations, suggesting that this region may consist of several distinct functional segments. Similarities between the organization of IS10's inverted repeat and those of other transposable elements are discussed. (ii) Base pairs 23-42 include a consensus binding sequence for one of the IS10 transposition host factors, IHF. The phenotypes of mutations in this region suggest that IHF is the major host factor for outside-end transposition activity in vivo and that base pairs throughout this region are important for the IHF interaction. (iii) Mutations in bp 43-61 do not affect outside-end transposition activity but do affect, in expected ways, previously identified determinants involved in expression and regulation of transposase. (iv) Some mutations in bp 23-42 also affect transposase expression; the possibility that IHF negatively regulates transcription initiation is discussed.

Multiple defects in Escherichia coli mutants lacking HU protein.

The HU protein isolated from Escherichia coli, composed of two partially homologous subunits, alpha and beta, shares some of the properties of eucaryotic histones and is a major constituent of the bacterial nucleoid. We report here the construction of double mutants totally lacking both subunits of HU protein. These mutants exhibited poor growth and a perturbation of cell division, resulting in the formation of anucleate cells. In the absence of HU, phage Mu was unable to grow, to lysogenize, or to carry out transposition.

Isolation of a formamidopyrimidine-DNA glycosylase (fpg) mutant of Escherichia coli K12.

The fpg+ gene of Escherichia coli coding for formamidopyrimidine-DNA glycosylase was previously cloned on a multicopy plasmid. The plasmid copy of the fpg+ gene was inactivated by cloning a kanamycin resistance gene into the open reading frame, yielding the fpg-1::Knr mutation. This mutation was transferred to the chromosome in the following steps: (i) linearization of the plasmid bearing the fpg-1::Knr mutation and transformation of competent bacteria (recB recC sbcB); (ii) selection for chromosomal integration of the fpg-1::Knr mutation; (iii) phage P1 mediated transduction of the fpg-1::Knr mutation in the AB1157 background. The resulting fpg- mutant exhibited no detectable Fapy-DNA glycosylase activity in crude lysates. The insertion mutation was localized by means of genetic crosses between mtl and pyrE, at 81.7 min on the E. coli linkage map. Sequence analysis confirmed this mapping and further showed that fpg is adjacent to rpmBG in the order fpg, rpmGB, pyrE. The formamidopyrimidine-DNA glycosylase defective strain does not show unusual sensitivity to the following DNA damaging treatments: (i) methylmethanesulfonate, (ii) N-methyl-N'-nitro-N-nitroso-guanidine, (iii) ultraviolet light, (iv) gamma-radiation. The fpg gene is neither part of the SOS regulon nor the adaptive response to alkylating agents.

A new generalizable test for detection of mutations affecting Tn10 transposition.

We describe here a new rapid screen that allows easy detection of transposon or host mutations that affect Tn10 transposition in Escherichia coli. This test involves a new Tn10 derivative called the "mini-lacZ-kanR fusion hopper" or mini-Tn10-LK for short. This element does not direct expression of beta-galactosidase when present at its original starting location on a suitably engineered plasmid or phage genome because it lacks appropriate transcription and translation start signals. However, transposition of this element into the chromosome of E. coli lacZ- bacteria leads to productive fusions in which the lacZ gene within the transposon is expressed from external chromosomal signals. Such fusions are readily detectable on MacConkey lactose indicator plates as red (Lac+) papillae inside of white (LacZ-) colonies. The length of time required to see red papillae appearing in a white colony sensitively and accurately reflects the transposition frequency of the mini-transposon within the colonies. Differences in times for color formation are sensitive enough that 10-fold differences in transposition frequency can readily be detected. This papillation assay can be used to identify mutant clones in which the frequency of Tn10 transposition is either increased or decreased. We have successfully used the assay to identify mutations in the terminal sequences of Tn10; mutations in the Tn10 transposase gene or the bacterial host can be isolated just as easily. This screen should be readily adaptable to transposable elements other than Tn10.

A Tn10-lacZ-kanR-URA3 gene fusion transposon for insertion mutagenesis and fusion analysis of yeast and bacterial genes.

We describe here a new variant of transposon Tn10 especially adapted for transposon analysis of cloned yeast genes; it can equally well be used for analysis of prokaryotic genes. We have applied this element to analysis of the LEU2, RAD50, and CDC48 genes of Saccharomyces cerevisiae. This transposon, nicknamed mini-Tn10-LUK, contains a lacZ gene without efficient transcription or translation start signals, an intact URA3 gene, and a kanR determinant. The lacZ gene can be activated by appropriate insertion of the element into an actively expressed gene. Other yeast genes can easily be substituted for URA3 in the available constructs. The mini-Tn10-LUK system has several important advantages. Transposition events occur in Escherichia coli at high frequency and into many different sites in yeast DNA. It is easy to obtain enough insertions to sensitively define the functional limits of a gene. Transposon insertions can be obtained in a single step by standard transposon procedures and can be screened immediately for phenotype either in yeast or in E. coli. The LacZ phenotypes of the insertion mutations provide a good circumstantial indication of the orientation of the target gene. Under favorable circumstances, usable lacZ protein fusions are created. Transposon insertion mutations obtained by this method directly facilitate additional genetic, functional, physical and DNA sequence analysis of the gene or region of interest.

A genetic analysis of primary products of bacteriophage lambda recombination.

Primary products of bacteriophage lambda recombination that display heterozygosity as a consequence of the presence of regions of heteroduplex DNA are rare in standard lambda crosses. Phage manifesting heterozygosity at a given allele are evident when recombinants, emerging from a cross, are selected for an exchange in a neighboring interval. We show that the abundance of such heterozygotes can be increased 10- to 20-fold by selection on an E. coli indicator that is defective in methyl-directed mismatch repair (mutL). Thus, the activity of the methyl-directed mismatch repair system is, at least in part, responsible for the low frequency of detectably heterozygous phage emerging from a standard cross. In a mutL indicator, many primary products of recombination are replicated without the intervention of mismatch repair.--The products of a six-factor phage cross have been plated on a mutL indicator allowing visual detection of those phage products heterozygous for one of the allelic pairs, cI. By genetic analysis, we show that the heteroduplex regions of these primary products of recombination are on the average about 4 kb in length and can include as much as half of the lambda genome.

3-Methyladenine residues in DNA induce the SOS function sfiA in Escherichia coli.

The induction by methylating agents of the SOS function sfiA was measured by means of a sfiA::lac operon fusion in Escherichia coli mutants defective in alkylation repair. The sfiA operon was turned on at a 10-fold lower concentration of methylmethane sulfonate or dimethyl sulfate in tagA strains, lacking specific 3-methyladenine-DNA glycosylase, than in wild-type strains. In contrast, the induction of sfiA by u.v. light was not affected by a tagA mutation. We confirm that tagA strains specifically accumulate 3-methyladenine in their DNA. We conclude that the persistence of 3-methyladenine in E. coli DNA most likely induces the SOS functions. Results on in vitro DNA synthesis further suggest that this induction is due to an unscheduled arrest of DNA synthesis at this lesion.

Cell-division control in Escherichia coli: specific induction of the SOS function SfiA protein is sufficient to block septation.

Blocks in DNA replication cause a rapid arrest of cell division in Escherichia coli. We have previously established that the function SfiA (SulA), induced under these conditions as part of the SOS response, is involved in this inhibition of division. To separate the effects of SfiA from those of other SOS functions, we have constructed a plac-sfiA operon fusion, permitting specific induction of SfiA protein by addition of the lac operon inducer isopropyl beta-D-thiogalactopyranoside (IPTG). In lon mutants, in which the unstable SfiA protein has a longer half-life, IPTG caused a rapid arrest of cell division. Under these conditions, there is no concomitant induction of the SOS response. IPTG also caused a rapid arrest of cell division in lon+ strains. These results demonstrate that induction of the SfiA protein is sufficient to cause inhibition of division. Mutations in the sfiB gene can suppress IPTG-induced SfiA-mediated inhibition of division. At higher SfiA concentrations, however, even sfiB mutants cease division; an additional mutation genetically inseparable from sfiB restores normal division. These observations reinforce the hypothesis that the SfiB protein, probably required for cell septation, is the target of action of the SfiA division inhibitor.

Use of DNA hybridization values to construct three-dimensional models of fluorescent pseudomonad relationships.

Three-dimensional models of the relationships among fluorescent pseudomonads were prepared from appropriately transformed percent DNA homology values. The transformation selected was f(x) = ( (1 - HOM/HOM)200, where HOM = fractional DNA homology and 200 is a scaling factor. Model accuracy was quite good as a plot of transformed DNA homology values versus model distances was essentially linear for homology values greater than 30%. The model suggested that bacterial strains within the fluorescent pseudomonads appear to be related in a three-dimensional continuum with no clear and easy "natural" demarcation into groups (i.e., species).

Novel mechanism of cell division inhibition associated with the SOS response in Escherichia coli.

Certain Escherichia coli strains were shown to possess a novel system of cell division inhibition, called the SfiC+ phenotype. SfiC+ filamentation had a number of properties similar to those of sfiA-dependent division inhibition previously described: (i) both are associated with the SOS response induced by expression of the recA(Tif) mutation, (ii) both are associated with cell death, (iii) both are amplified in mutants lacking the Lon protease, and (iv) both are suppressed by sfiB mutations. SfiC+ filamentation and sfiA-dependent division inhibition differed in (i) the physiological conditions under which loss of viability is observed, (ii) the extent of amplification in lon mutants, (iii) their genetic regulation (SfiC+ filamentation is not under direct negative control of the LexA repressor), and (iv) their genetic determinants (SfiC+ filamentation depends on a locus, sfiC+, near 28 min on the E. coli map and distinct from sfiA).

Role of the sfiA-dependent cell division regulation system in Escherichia coli.

Several authors have suggested that the SOS-associated (sfiA-dependent) system of division inhibition, normally induced by perturbations of DNA replication, also regulates steady-state (unperturbed) cell division. The present work shows that mean cell mass is identical in sfiA+ and sfiA mutant cultures during steady-state growth, that mass adjustment is identical after shift up, that sfiA expression is not induced by shift up, and that a sfiA mutation does not cause aberrant chromosome segregation.

Effect of suppressors of SOS-mediated filamentation on sfiA operon expression in Escherichia coli.

In Escherichia coli, the cell division block observed during the SOS response requires the product of the sfiA gene, whose expression is regulated negatively by the LexA repressor and positively by the RecA protease. We have studied the effect on sfiA expression of sfiA, sfiB, infA, and infB mutations, which are known to affect SOS-associated filamentation. To measure sfiA expression in the different strains, we first constructed a lambda transducing phage carrying an sfiA::lac operon fusion. Mutations at the sfiA locus (dominant and recessive) and the sfiB locus (recessive) had no effect on sfiA expression. The mutations tif (at the recA locus) and tsl (at the lexA locus) are known to induce filamentation and a high level of sfiA expression at 42 degrees C. The infB1 mutation, which suppresses filamentation in a tif tsl strain at 42 degrees C, reduced sfiA expression at 42 degrees C in tif tsl infB1 and tsl infB1 strains but not in a tif infB1 strain. The infA3 mutation, which suppresses tif-mediated filamentation, reduced induction of sfiA expression in a tif infA3 strain at 42 degrees C or after UV irradiation. The isolation and characterization of sfiA constitutive strains revealed only lexA-linked mutations in a sfiA-background, suggesting that LexA is the only readily eliminated repressor of the sfiA gene. Nevertheless, the infA and infB mutations could define elements involved in the regulation of sfiA expression.

SOS chromotest, a direct assay of induction of an SOS function in Escherichia coli K-12 to measure genotoxicity.

We present and evaluate the SOS chromotest, a bacterial test for detecting DNA-damaging agents. It is a colorimetric assay based on the induction by these agents of the SOS function sfiA, whose level of expression is monitored by means of a sfiA::lacZ operon fusion. The response is rapid (a few hours), and does not require survival of the tester strain. Dose-response curves for various chemicals include a linear region. The slope of this region is taken as a measure of the SOS inducing potency. Comparison for a number of substances of known genotoxicity of the SOS inducing potency determined in the SOS chromotest with the mutagenic potency determined in the Salmonella assay (mutatest) revealed a striking quantitative correlation over more than 7 orders of magnitude. The sensitivity of the SOS chromotest (lowest amount detected) is equal to that of the mutatest and generally 4-40 times higher than that of a phage induction assay (inductest). From a practical point of view our observations contribute to the validation of the SOS chromotest as a test for detecting genotoxins and in particular genotoxic carcinogens. From a theoretical standpoint the results suggest that mutagenic potency measured in the mutatest reflects the level of induction of an SOS function and that most genotoxins are inducers of the SOS response in bacteria.

DNA replication and indirect induction of the SOS response in Escherichia coli.

The SOS response can be induced indirectly in Escherichia coli by infection with UV irradiated bacteriophage P1, lambda or M13. Induction, monitored quantitatively by means of a sfiA::lac operon fusion, was stronger with the plasmid phage P1 than with lambda, but the kinetics were similar, showing that plasmid and non-plasmid phages are not fundamentally different in their ability to produce indirect induction. In the absence of lambda DNA replication the level of induction was strongly reduced, indicating that the attempt to replicate damaged DNA results in induction of the SOS response. The slight residual induction observed in the absence of DNA replication suggests the existence of a second pathway leading from DNA lesions to induction of the SOS response.

How Escherichia coli sets different basal levels in SOS operons.

The recA and sfiA genes of Escherichia coli are SOS operons regulated negatively by the LexA repressor. The steady state level of expression of recA is 10-fold higher than that of sfiA, as measured by means of recA::lac and sfiA::lac operon fusions. To study the molecular basis of this difference, we have compared the expression of these two operons in strains in which the concentration of LexA repressor was normal (lexA+), zero (spr amber mutation) or higher than normal (plasmid pJL45, carrying the lexA gene linked to the lac promoter). The results indicate (i) that the recA promoter is about 4 times stronger than the sfiA promoter (as measured in the spr strains), (ii) that neither operon has a physiologically significant level of lexA-independent expression (pJL45 strains), and (iii) that the recA operator has about 2.5 times lower affinity than the sfiA operator for LexA repressor (comparison of lex+ and spr strains). Considering our previous results that the sfiA operon (high operator affinity of LexA) is derepressed very rapidly after inducing treatments and that the recA operon (low operator affinity) is repressed very rapidly when induction is stopped, we conclude that differences in operator affinity do not affect inducibility but serve only to set the basal levels of the different SOS functions.

The SOS chromotest: direct assay of the expression of gene sfiA as a measure of genotoxicity of chemicals.

We used a gene fusion, placing the lacZ gene encoding beta-galactosidase under the control of the sfiA promoter, to construct a new tester strain for genotoxic agents. The assay is performed in a few hours and involves simple enzymatic assays. The dose response curves contain a linear portion which enables to define the SOS Inducing Potency (SOSIP) of compounds. For the compounds tested SOSIPs extend over 7 decades and correlate generally well with the mutagenic potency assayed in the Salmonella/microsome assay (Mutatest) and in a phage induction assay (Inductest). Sensitivities (lowest amount detected) are comparable in the SOS Chromotest and Mutatest but lower in the Inductest. Our results suggest that at least part of the response in the Mutatest depends on the induction of an SOS function, and that most of the genotoxins are inducer of the SOS system -i.e. can lead to activation of the RecA protease.