Complementation studies with the repair-deficient uvrD3, uvrE156, and recL152 mutations in Escherichia coli

Summary Previous work showed that the mutations uvrD3, uvrE156, and recL152 were closely linked and increased UV-sensitivity. They were phenotypically distinguishable in that only the uvrD3 mutation significantly decreases host cell reactivation of UV-irradiated phage (Hcr^-) and repair of methylmethane sulfonate (MMS)-induced damage, and only the uvrE156 mutation increased mutation rates (Mut^-). MMS-resistant revertants of a uvrD3 mutant were still UV-sensitive and fell into two phenotypic classes, Hcr^- Mut⁺ (non-mutator) and Hcr⁺ Mut^-. In this work complementation tests were done by examining UV-and MMS-sensitivity and host cell reactivation in heterogenotes containing combinations of uvrD3, uvrE156, recL152, and the MMS-resistant mutations derived from uvrD3. The mutations could not complement each other in the repair of UV-damage, the one trait all had in common, indicating that they were in one gene. For the most part, the different mutations were able to complement each other in respect to traits in which one was deficient and the other had wild type activity.     

Interaction of super-repressible and dominant constitutive mutations for the synthesis of galactose pathway enzymes in Saccharomyces cerevisiae

Summary Two dominant uninducible mutant alleles in the gal80 locus were identified. The GAL80 ^s-1 and GAL80 ^s-2 mutants showed novel phenotypes in response to the newly isolated GAL81-1 mutant allele, a dominant constitutive mutation linked to the gal4 locus; the GAL80 ^s-1 GAL81-1 strain was inducible and the GAL80 ^s-2 GAL81-1 strain was uninducible. Many galactose positive revertants from the GAL80 ^s-2 GAL81-1 strain were isolated. It was proved that each revertant was due to a secondary mutation either in the gal80 or GAL81 locus, whereas revertants due to mutation at the supposed controlling site for the structural gene cluster of the galactose-pathway enzymes have not been isolated.This study was supported in part by grant no. 048164 to Y. Oshima from the Scientific Research Fund of the Ministry of Eduction, Japan     

Effects of MULTIFOLIATE-PINNA, AFILA, TENDRIL-LESS and UNIFOLIATA genes on leafblade architecture in Pisum sativum

In order to dissect the genetic regulation of leafblade morphogenesis, 16 genotypes of pea, constructed by combining the wild-type and mutant alleles of MFP, AF, TL and UNI genes, were quantitatively phenotyped. The morphological features of the three domains of leafblades of four genotypes, unknown earlier, were described. All the genotypes were found to differ in leafblade morphology. It was evident that MFP and TL functions acted as repressor of pinna ramification, in the distal domain. These functions, with and without interaction with UNI, also repressed the ramification of proximal pinnae in the absence of AF function. The expression of MFP and TL required UNI function. AF function was found to control leafblade architecture multifariously. The earlier identified role of AF as a repressor of UNI in the proximal domain was confirmed. Negative control of AF on the UNI-dependent pinna ramification in the distal domain was revealed. It was found that AF establishes a boundary between proximal and distal domains and activates formation of leaflet pinnae in the proximal domain.     

Induced mutagenesis in Ustilago maydis

Summary A UV-revertible mutant of the nar1 structural gene for nitrate reductase was isolated in wildtype (nar ⁺ nir ⁺) Ustilago maydis. It proved to be vigorously revertible by gamma rays as well. Genetic analysis revealed that the strain carried a single, nonleaky, recessive allele (nar1-m) with an unusually high spontaneous reversion rate (3×10^-5/div.). Reliable reversion frequencies were determined with a special agar medium that reduced the normally high level of residual growth observed on nitrate minimal agar. Radiation-induced reversion frequencies in the homozygous diploid were approximately twice those in the hapliod. Following crosses to wild type, two revertants (one spontaneous and one UV-induced) were found to map at nar1. Although the molecular basis of nar1-m reversion is not known, available data suggest that some form of point mutation is involved.     

The dominant Drop eye mutations of Drosophila melanogaster define two loci implicated in normal eye development

The three existing dominant gain-of-function Drop alleles, Dr ¹, Dr ^Mio and Dr ^We , previously assumed to define a single locus, severely disrupt eye development. Genetic analysis of ethylmethanesulphonate (EMS) and irradiation-induced revertants revealed that the Drop mutations define two loci: the Drop locus, which is defined by the Dr ¹ and Dr ^Mio mutants, and a separate locus defined by the Dr ^We mutation, which has been renamed Wedge. The majority of the Dr ¹ and Dr ^Mio revertants are embryonic lethal in trans, mutant embryos exhibiting trachea that fail to join the Filzkörper, thus revealing a role for the Drop gene in embryogenesis. Clonal analysis of lethal revertant alleles suggests a role for both genes in eye development. In the Drop homozygous mutant clones, the outer photoreceptor cells R1–R6 develop aberrantly. Wedge, however, is not required by the developing photoreceptor cells but its absence does disrupt normal ommatidial alignment. Although the Drop and nearby string loci were shown to be genetically distinct, both Dr ¹ and Dr ^Mio were found to interact in trans with lesions at the string locus, causing loss and derangement of bristles and loss of neuromuscular coordination.     

Isolation and characterization of dam+ revertants and suppressor mutations that modify secondary phenotypes of dam-3 strains of Escherichia coli K-12

Summary Bacteria mutant in the dam (DNA adenine methylation) gene and in either recA or recB or recC genes are inviable (Virm^- phenotype). From crosses between dam-3 bacteria and recA1 or recB21 recC22 strains, Vrm⁺ recombinants were recovered. Among these recombinants, Dam⁺ revertants were present which did not show the phenotypes normally associated with dam-3 bacteria. Three classes of indirectly suppressed strains (dam-3 genotype) were also recovered which showed alterations in the secondary phenotypes normally associated with dam-3 bacteria. These strains contained a second unlinked mutation in either mutL or mutS or sin. In addition, mutation in either sbcA or sbcB suppresses the Vrm^- phenotype of dam-3 recB21 recC22 strains.     

Tolerance of low pH in Schizosaccharomyces pombe requires a functioning pub1 ubiquitin ligase

A strain of Schizosaccharomyces pombe carrying a disrupted Na⁺/H⁺ antiporter gene (sod2::sup3-5), in addition to the common auxotrophic mutations, ade6-216, ura4-D18 and leu1-32, is highly sensitive to media adjusted to pH 6.9. Reversion analysis of this strain yielded a group of revertants capable of growth at pH 6.9. Two of the revertants elongated and failed to form colonies at pH 3.5. Genetic characterization of one of the pH-sensitive elongated strains, J227, showed the presence of two independently segregating mutations. One, pub1 ( protein ubiquitin ligase 1), has recently been reported as an E3 protein ubiquitin ligase involved in cdc25 turnover. The second has been named elp3-1 (elongated at low pH). Genetic dissection of the original strain revealed that poor growth at high pH was due to the presence of the auxotrophic markers, suggesting a possible inhibitory effect of high pH on the function of permeases responsible for uptake of the necessary nutrients. Suppression of the high pH sensitivity required the presence of both the pub1-1 and elp3-1 mutations. While the pub1-1 mutation reduced the capacity of cells to tolerate relatively moderate concentrations of LiCl (3 mM) in liquid culture, it was capable of partially suppressing the extreme Li⁺ sensitivity caused by the sod2 disruption. Under these conditions, the growth of pub1-1 sod2::ura4 double mutant cells was improved over that of either pub1-1 or sod2::ura4 cells. The elp3-1 mutation had no effect on the Li⁺ tolerance in either wild-type or sod2::ura4 backgrounds. pub1-1 cells are elongated and incapable of colony formation at pH 3.5. In contrast, elp3-1 cells are elongated at pH 3.5 and pH␣5.5 (the normal pH of minimal medium) but can form colonies under both conditions. J227 cells are significantly longer than either single mutant at pH 3.5 and do not form colonies but are visually similar to elp3-1 cells at pH 5.5. Complementation cloning in the J227 background yielded a genomic clone of pub1, allowing us to define the intron-exon structure of the gene. Sequences with high homology to the predicted amino acid sequence of pub1 have been identified in Saccharomyces cerevisiae (RSP5/NPI1), human (hRPF1), mouse (mNedd4), and rat (rNedd4). Based on the nature of our mutant selection, the pH-sensitive phenotype of the strains selected, and the known involvement of RSP5/NPI1 in membrane permease turnover in S. cerevisiae, we hypothesize a role for pub1, either directly or indirectly, in regulating membrane transport processes. This is further supported by the broad range of effects that the pub1-1 mutation exerts on overall performance of cells at high and low external pH, and in the presence of toxic levels of Li⁺. Received: 12 September 1996 / Accepted: 19 December 1996     

Genetic analysis of an essential cytoplasmic domain of Escherichia coli SecY based on resistance to Syd, a SecY-interacting protein

We previously described a dominant negative secY ^-d 1 allele in Escherichia coli, whose product interferes with protein export, presumably by sequestering SecE, the stabilizing partner of SecY. Syd is the product of a multicopy suppressor of the secY ^-d 1 phenotype, and its overproduction preferentially stabilizes the wild-type SecY protein. In contrast, overproduction of Syd is toxic to the secY24 mutant, which shows a partial defect in SecY-SecE interaction. We isolated Syd-resistant revertants from the secY24 mutant. Pseudo-reversions mapped to sites at or near the secY24 mutation site (Gly240→Asp). The secY249 mutation (Ala249→Val) intragenically suppressed Syd sensitivity, but not the temperature-sensitive Sec phenotype of the secY24 mutation. The SecY249 mutant protein shows a reduced capacity to be stabilized by Syd, suggesting that the mutation weakens the SecY-Syd interaction. The other two mutations changed residue 240 (the site of the secY24 alteration) to Asn (secY245) or Ala (secY241) and restored the ability of the cell to export protein. Although the secY245 mutant retained some sensitivity␣to Syd overproduction, the secY241 mutant was completely Syd-resistant. Furthermore, the secY241 mutation seemed to represent a “hyper reversion” with respect to the SecY-SecE interaction. Protein export in this mutant was no longer sensitive to SecY^-d1. When the secY ^-d 1 mutation was combined intragenically with secY241, the resulting double mutant gene (secY ^-d 1–241) showed an increased ability to interfere with protein export. On the basis of our model for SecY^-d1, these results suggest that the secY241 alteration enhances SecY-SecE interaction. These results indicate that residue 240 of SecY is crucial for the interaction between the cytosolic domains of SecY and SecE required for the establishment of the translocase complex. Received: 20 October 1997 / Accepted: 1 December 1997     

Initiation of DNA replication in Escherichia coli

Summary When E. coli F⁺ cells carrying the dna-167 or dnaC2 mutation, which causes the temperature-sensitive initiation of DNA replication, are exposed to a non-permissive temperature to stop the replication of chromosome and F factor, and then transferred back to a permissive temperature with the addition of chloramphenicol, one round of the chromosomal replication occurs, but further replication is inhibited. Under these conditions, F DNA replicates coincidentally with the initiation of the chromosomal replication in both strains. When rifampicin is added to the cells upon lowering of the temperature, the chromosome can not replicate in the F⁺ dna-167 strain, but can do so in the F⁺ dnaC2 strain. F DNA can replicate in both of the mutant strains under these conditions.     

Reversion of the gal3 mutation of Escherichia coli: Partial deletion of the insertion sequence

Summary The gal3 mutation of E. coli is an insertion of a DNA sequence, 1,100 base pairs in length, into the operator-promoter region of the galactose operon. This mutation reverts spontaneously to gal⁺ by excision of the insertion to produce stable, inducible revertants, or by tandem duplications of the gal operon to produce unstable, constitutive revertants. The nature of a third class of revertants, which are stable and constitutive, is the subject of the present study.The stable, constitutive class of revertants included approximately 30% of all gal⁺ revertants obtained from a gal3() strain. Although the constitutive reversions could be transduced by , the efficiency was found to be extremely poor and the rare transductants which did appear seemed to originate from abnormal transducing particles. It was concluded that these reversions were not normally packaged by .In order to facilitate the packaging of these reversions, the chlD-pgl region was deleted from the parent gal3() strain. Unexpectedly, the gal3 mutation in the majority of these deletions reverted to produce stable, constitutive reversions exclusively. The explanation proposed was that the chlD-pgl deletions had also removed part of the gal operator-promoter up to the gal3 insertion, so that simple excisions of the insertion yielded stable, constitutive revertants by connecting the gal structural genes to a different promoter. These revertants were not considered to be true representatives of the stable, constitutive class. The specificity of deletion end-points at the insertion was found only in the gal3() strain, and not in gal ⁺, gal ⁺(), or gal3 strains. Moreover, the frequency of spontaneous chlD-pgl deletions increased 10- to 15-fold in presence of the gal3 insertion.A gal phage bearing a true stable, constitutive reversion (gal ^c 200) was isolated from the revertant strain by subsequent deletion of the chlD-pgl segment (31). Electron micrographs of gal ⁺ and gal ^c 200 31(chlD pgl) DNA heteroduplexes were interpreted to indicate that the stable, constitutive reversion had arisen by a deletion of 3/4 of the gal3 insertion sequence.The main conclusions are: (i) the stable, constitutive reversions of gal3 can arise by partial deletions of the insertion sequence, apparently by elimination of the nucleotide sequence which causes polarity; (ii) the chlD-pgl deletions may exhibit preferential termination at the right extremity of the gal3 insertion in presence of prophage ; and (iii) the gal3 insertion appears to inhibit the production of gal particles by providing a nucleotide sequence which is recognized and degraded by a specific endonuclease. It is suggested that inhibition of transducing particle formation by gal3 and the preferred termination of deletions at gal3 might represent related phenomena.     

Revertants from RNase III negative strains of Escherichia coli

Summary E. coli strains carrying the rnc-105 allele do not show any level of RNase III in extracts, grow slower than rnc ⁺ strains at temperatures up to 45°C and fail to grow at 45°C. Revertants which can grow at 45°C were isolated. The vast majority of them still do not grow as fast as rnc ⁺ strains and did not regain RNase III activity. The mutation(s) which caused them are suppressor mutations (physiological suppressors) which do not map in the immediate vicinity of the rnc gene. A few of the revertants regain normal growth, and contain normal levels of RNase III. They do not harbor the rnc-105 allele and therefore are considered to be true revertants. By using purines other than adenine it was possible to isolate rnc ⁺ pur ^- revertants from an rnc ^- pur ^- strain with relative ease. They behaved exactly like the true rnc ⁺ revertants isolated from rnc ^- strains at 45°C.A merodiploid strain which contains the rnc ⁺ gene on an episome behaves exactly like an rnc ⁺ strain with respect to growth and RNA metabolism, eventhough its specific RNase III activity is about 60% of that of an rnc ⁺ strain; thus the level of RNase III is not limiting in the cell.The rnc ^- strains show a characteristic pattern of transitory molecules, related to rRNA, 30S, 25S, p23 and 18S, which are not observed in rnc ⁺ strains. This pattern is unchanged in rnc ^- strains and in the revertants which are still lacking RNase III, regardless of the temperature in which RNA synthesis was examined (30° to 45°C). On the other hand, in the rnc ⁺ strains as well as in the true revertants and the rnc ⁺/rnc ^- merodiploid, the normal pattern of p16 and p23 is observed at all temperatures. These findings suggest that all the effects observed in RNase III^- strains are due to pleiotropic effects of the rnc-105 allele, and that the enzyme RNase III is not essential for the viability of the E. coli cell.     

Genetic studies with a phosphoglucose isomerase mutant of Saccharomyces cerevisiae.

Summary A mutation pgi1 in the yeast Saccharomyces cerevisiae conferring deficiency of the glycolytic enzyme glucose 6-phosphate isomerase is characterised genetically. The mutation segregates 2⁺:2^- in tetrads from diploids heterozygous for the mutant phenotype. The mutation is semi-dominant and is located on the right arm of chromosome II in the order: tsm134-lys2-pgi1-tyr1 approximately 15 map units from tyr1. The mutation pgi1 defines the structural gene of glucose 6-phosphate isomerase and can be suppressed intragenically giving revertants that have an unstable enzyme. In one temperature-sensitive revertant no enzyme activity in excess of the mutant level could be detected although fructose 6-phosphate was converted to glucose 6-phosphate in vivo. The suppressor locus in this revertant is dominant and is unlinked to the pgi1 locus.     

Gene order in the qa gene cluster of Neurospora crassa

Summary Four different types of crosses have been used to establish the order of the four genes in the qa gene cluster of Neurospora crassa, which encode the following proteins involved in the inducible catabolism of quinic acid: a regulatory (activator) protein (qa-1), catabolic dehydroquinase (qa-2), quinate dehydrogenase (qa-3), and dehydroshikimate dehydrase (qa-4). The four crosses involved (1) the ordering of the four qa genes relative to the closely-linked me-7 locus; (2) the ordering of the three other qa genes relative to a qa-1 ^S mutant; (3) the use of a three factor cross-qa-3xqa-4 qa-2 and (4) the use of four factor crosses-qa-1 ^S xqa-3 qa-4 qa-2. The results of all four types of crosses agree in establishing an apparently definitive proximal to distal order, within the right arm of linkage group VII, i.e., qa-1 qa-3 qa-4 qa-2 me-7.The significance of a definitive establisment of the gene order within the qa cluster for an understanding of the organization and mechanism of genetic regulation in this cluster is discussed.     

Genetic analysis of revertants for the nitrate reductase function of Nicotiana plumbaginifolia

Summary Spontaneous revertants of nitrate reductase (NR)-less mutants were isolated by screening for nitrate utilization in diploid NR^– protoplast cultures of Nicotiana plumbaginifolia. The revertants contained in vivo NR activity in the case of apoenzyme mutants (nia) as well as of a cofactor-deficient (cnx) mutant. Revertants of the NIA type proved to be tetraploid, and genetic analysis showed that only one out of the four NR structural genes had reverted to a functional allele.     

Spore control (Sco) mutations in Bacillus subtilis

Summary Spore control (Sco) mutants were isolated after nitrosoguanidine-induced mutagenesis of germinated spores. They were recognized as colonies showing high proteolytic activity on protein-agar (generally elastin-agar) test plates. Fourteen such mutants were isolated. The Sco mutations were transferred by transformation into an isogenic collection of genetically marked strains. Most of them appeared to be single mutations. Transduction experiments permitted the localisation of six Sco mutants in three loci, all in the argC-metC region. ScoA is located between argC and metC, ScoB is to the right of metC and ScoC is to the left of argC. ScoC and the previously described catA mutation are probably placed in the same gene.Two ScoC strains also appear to carry a second mutation, ScoD, probably localised in the same locus as ScoB or in a locus close to it. Eight other Sco mutations, apparently unlinked to the argC-metC region, were not localised. The results indicate complex regulation of sporulation-associated products such as the proteases, dependent on several genes.     

Revertants of a streptomycin-resistant, oligosporogenous mutant ofBacillus subtilis

Summary Revertants of a streptomycin-resistant (Str^R), oligosporogenous (Spo^-) mutant ofBacillus subtilis were selected for the ability to sporulate. The revertants obtained fell into two phenotypic classes: Str^S Spo⁺ (streptomycin-sensitive, sporeforming), which arose by reversion of the streptomycin resistance mutations of the parent strain; and Str^R Spo⁺, which arose by the acquisition of additional mutations, some of which were shown to affect ribosomal proteins. Alterations of ribosomal proteins S4 and S16 in the 30S subunit and L18 in the 50S subunit were detected in Str^R Spo⁺ revertants by polyacrylamide gel electrophoresis. Streptomycin resistance of the parental strain and the Str^R revertants was demonstrated to reside in the 30S ribosomal subunit. The second site mutations of the revertants depressed the level of streptomycin resistance in vivo and in the in vitro translation of phage SP01 messenger ribonucleic acid (mRNA) relative to the resistance exhibited by the Str^R parental strain. The Str^R parent grew slowly and sporulated at approximately 1% of the wild type level. The Str^S revertants closely resembled the wild type strain with regard to growth and sporulation. The Str^R revertants grew at rates intermediate between those of the Str^R parent and wild type, and sporulated at wild type levels.     

Methionine and glutamine transport systems in D-methionine utilising revertants of Salmonella typhimurium

Summary In Salmonella typhimurium, methionine auxotrophs such as metB can use D-methionine as a methionine source. MetP mutations prevent this growth since D-methionine can enter only via the metP high-affinity methionine transport system. D-methionine utilising revertants (Dmu⁺) were selected from metB23 metP760 (HU76) following nitrosoguanidine mutagenesis. The properties of two such revertants, HU206 and HU415, indicated that reversion was not due to backmutation of the metP760 mutation. Genetic analysis indicated that each strain possessed two mutations, designated dmu and gln, in addition to the original metB23 and metP760 mutations.The dmu mutation restores ability to grow on D-methionine, partly restores D- and L-methionine transport activity, and makes the cells particularly sensitive to inhibition by L-glutamine while growing on D but not L-methionine. The growth inhibition by L-glutamine was shown to be caused by competition by L-glutamine for D-methionine transport by the high-affinity methionine system. The gln mutation greatly reduces activity of the high-affinity glutamine transport system. The Dmu⁺ strains are also partly defective in the glutamine low-affinity transport system, possibly because the partially-restored methionine high-affinity system, or a component of this system, functions in the transport of glutamine by its low-affinity system.     

Isolation of the mini insertions IS6 and IS7 of E. coli

Summary The mini IS elements IS6 and IS7 have been detected in constitutive gal ⁺ revertants of galOP-308::IS2 (I), in which the expression of the gal operon is turned off by IS2 in orientation I. Both, IS6 and IS7, are integrated into IS2 proximal to the gal structural genes. IS6 is 115 base pairs long and causes 50% constitutive expression of the gal genes. IS7 is only 65 base pairs long and the gal operon is expressed 20% constitutively compared to the gal ⁺ wild type operon. Both IS6 and IS7 are excised frequently, in the absence of selective pressure. These findings are discussed with respect to the evolution of gene expression.