Dominant Suppressors of Yeast Actin Mutations That Are Reciprocally Suppressed

A gene whose product is likely to interact with yeast actin was identified by the isolation of pseudorevertants carrying dominant suppressors of the temperature-sensitive (Ts) act1-1 mutation. Of 30 independent revertants analyzed, 29 were found to carry extragenic suppressor mutations and of these, 24/24 tested were found to be linked to each other. This linkage group identifies a new gene SAC6, whose product, by several genetic criteria, is likely to interact intimately with actin. First, although act1-1 sac6 strains are temperature-independent (Ts+), 4/17 sac6 mutant alleles tested are Ts in an ACT1+ background. Moreover, four Ts+ pseudorevertants of these ACT1+ sac6 mutants carry suppressor mutations in ACT1; significantly, three of these are again Ts in a SAC6+ background, and are most likely new act1 mutant alleles. Thus, mutations in ACT1 and SAC6 can suppress each other's defects. Second, sac6 mutations can suppress the Ts defects of the act1-1 and act1-2, but not act1-4, mutations. This allele specificity indicates the sac6 mutations do not suppress by simply bypassing the function of actin at high temperature. Third, act1-4 sac6 strains have a growth defect greater than that due to either of the single mutations alone, again suggesting an interaction between the two proteins. The mutant sac6 gene was cloned on the basis of dominant suppression from an act1-1 sac6 mutant library, and was then mapped to chromosome IV, less than 2 cM from ARO1.     

Genetic and behavioral analysis of flagellar switch mutants of Salmonella typhimurium.

At the interface between the sensory transduction system and the flagellar motor system of Salmonella typhimurium, the switch complex plays an important role in both sensory transduction and energy transduction. To examine the function of the switch complex, we isolated from 10 cheY mutants 500 pseudorevertants with a suppressor mutation in one of the three genes (fliG, fliM, and fliN) encoding the switch complex. Detailed mapping revealed that these suppressor mutations were localized to several segments of each switch gene, suggesting localization of functional sites on the switch complex. These switch mutations were introduced into the wild-type background and into a chemotaxis deletion background. Behavior of the pseudorevertants and their derivatives (1,500 strains in all) was observed by light microscopy. In the chemotaxis deletion background, about 70% of the switch mutants showed smooth swimming and the rest showed more or less tumbly swimming. There was some correlation between the mutational sites and the swimming patterns in the chemotaxis deletion background, suggesting that there is segregation of functional sites on the switch complex. The interaction of the switch complex with the chemotaxis protein, CheY, and the stochastic nature of switching in the absence of CheY are discussed.     

Suppressors of gene 32 am mutants that specifically overproduce P32 (unwinding protein) in bacteriophage T4.

A gene 32 amber (am) mutant, amNG364, fails to grow on Escherichia coli Su3+ high temperatures, suggesting that the tyrosine residue inserted at the am codon by Su3+ leads to a temperature-sensitive gene 32 protein (P32). By plating amNG364 on E. coli Su3+ 45 degrees C, several pseudorevertants were found that proved to contain a suppressor (su) mutant in addition to the original am mutation. Crosses of two of these amNG364su strains to am+ phage indicated that the suppressors themselves are in or close to gene 32. Phage strains carrying either of the two su mutations, without amNG364, grew normally. When cells were infected by these su mutants and the proteins produced were examined by sodium dodecyl sulfate-gel electrophroesis, specific overproduction of P32 was found. Maximum overproduction compared to am+ phage was 6.6-fold for one su mutant and 2.4-fold for the other. Other proteins were produced in normal amounts and in normal time sequence. When amNG364su phage were allowed to infect E. coli S/6/5(Su-), the gene 32 am fragments produced were present at the same derepressed levels as in an infection by amNG364 without a suppressor. The suppressor mutations are interpreted as causing derepression of P32 by altering sites in this autogenously regulated protein involved in template recognition. Previously, specific derepression of gene 32 had only been shown using gene 32 conditional lethal mutants grown under restrictive conditions. We have shown that P32 can also be derepressed under permissive conditions, indicating that loss of P32 function is not necessary for specific derepression.     

Genetic evidence for a switching and energy-transducing complex in the flagellar motor of Salmonella typhimurium.

The flaAII.2, flaQ, and flaN genes of Salmonella typhimurium are important for assembly, rotation, and counterclockwise-clockwise switching of the flagellar motor. Paralyzed and nonchemotactic mutants were subjected to selection pressure for partial acquisition of motility and chemotaxis, and the suppressor mutations of the resulting pseudorevertants were mapped and isolated. Many of the intergenic suppressor mutations were in one of the other two genes. Others were in genes for cytoplasmic components of the chemotaxis system, notably cheY and cheZ; one of the mutations was found in the cheA gene and one in a motility gene, motB. Suppression among the three fla genes was allele specific, and many of the pseudorevertants were either cold sensitive or heat sensitive. We conclude that the FlaAII.2, FlaQ, and FlaN proteins form a complex which determines the rotational sense, either counterclockwise or clockwise, of the motor and also participates in the conversion of proton energy into mechanical work of rotation. This switch complex is probably mounted to the base of the flagellar basal body and, via binding of the CheY and CheZ proteins, receives sensory information and uses it to control flagellar operation.     

Isolation and genetic analysis of a mutation that suppresses the auxotrophies of superoxide dismutase-deficient Escherichia coli K12

Summary The most striking phenotype associated with superoxide dismutase (SOD) deficiency in Escherichia coli is the inability to grow in aerobic minimal medium, which is due to the sensitivity of several amino acid biosynthetic pathways to superoxide. We have isolated two classes of pseudorevertants that grow on minimal medium at modest rates. Of these, the class that exhibited the faster growth carries mutations at a single locus, denoted ssa, which was mapped to 4 min on the E. coli chromosome. This class constituted the majority of the spontaneous pseudorevertants that were selected by the transfer of independent SOD-deficient cultures in minimal medium from anaerobic to aerobic growth conditions. Pseudoreversion at ssa suppressed requirements for a variety of unrelated amino acid supplements. Further, the SOD-deficient strains were unable to assimilate diaminopimelic acid from the growth medium, whereas the ssa pseudorevertants did so. The viability of these pseudorevertants indicates that superoxide-sensitive biosynthetic enzymes do retain some function in SOD-deficient cells during aerobic growth.     

Suppressor analysis of the MotB(D33E) mutation to probe bacterial flagellar motor dynamics coupled with proton translocation

MotA and MotB form the stator of the proton-driven bacterial flagellar motor, which conducts protons and couples proton flow with motor rotation. Asp-33 of Salmonella enterica serovar Typhimurium MotB, which is a putative proton-binding site, is critical for torque generation. However, the mechanism of energy coupling remains unknown. Here, we carried out genetic and motility analysis of a slowly motile motB(D33E) mutant and its pseudorevertants. We first confirmed that the poor motility of the motB(D33E) mutant is due to neither protein instability, mislocalization, nor impaired interaction with MotA. We isolated 17 pseudorevertants and identified the suppressor mutations in the transmembrane helices TM2 and TM3 of MotA and in TM and the periplasmic domain of MotB. The stall torque produced by the motB(D33E) mutant motor was about half of the wild-type level, while those for the pseudorevertants were recovered nearly to the wild-type levels. However, the high-speed rotations of the motors under low-load conditions were still significantly impaired, suggesting that the rate of proton translocation is still severely limited at high speed. These results suggest that the second-site mutations recover a torque generation step involving stator-rotor interactions coupled with protonation/deprotonation of Glu-33 but not maximum proton conductivity.     

Interaction between FliE and FlgB, a proximal rod component of the flagellar basal body of Salmonella

FliE is a flagellar basal body protein of Salmonella whose detailed location and function have not been established. A mutant allele of fliE, which caused extremely poor flagellation and swarming, generated extragenic suppressors, all of which mapped to flgB, one of four genes encoding the basal body rod; the fliE flgB pseudorevertants were better flagellated and swarmed better than the fliE parent, especially when the temperature was reduced from 37 to 30 degrees C. Motility of the pseudorevertants in liquid culture was markedly better than motility on swarm plates; we interpret this to mean that reduced flagellation is less deleterious at low viscous loads. Overproduction of the mutant FliE protein improved the motility of the parental fliE mutant and its pseudorevertants, though not to wild-type levels. Overproduction of suppressor FlgB (but not wild-type FlgB) in the fliE mutant also resulted in improved motility. The second-site FlgB mutation by itself had no phenotype; cells swarmed as well as wild-type cells. When overproduced, wild-type FliE was dominant over FliE-V99G, but the reverse was not true; that is, overproduced FliE-V99G was not negatively dominant over wild-type FliE. We conclude that the mutant protein has reduced probability of assembly but, if assembled, functions relatively well. Export of the flagellar protein FlgD, which is known to be FliE dependent, was severely impaired by the FliE-V99G mutation but was significantly improved in the suppressor strains. The FliE mutation, V99G, was close to the C terminus of the 104-amino-acid sequence; the suppressing mutations in FlgB were all either G119E or G129D, close to the C terminus of its 138-amino-acid sequence. Affinity blotting experiments between FliE as probe and various basal body proteins as targets and vice versa revealed strong interactions between FliE and FlgB; much weaker interactions between FliE and other rod proteins were observed and probably derive from the known similarities among these proteins. We suggest that FliE subunits constitute a junction zone between the MS ring and the rod and also that the proximal rod structure consists of FlgB subunits.     

Mutations in the rpoH (htpR) gene of Escherichia coli K-12 phenotypically suppress a temperature-sensitive mutant defective in the sigma 70 subunit of RNA polymerase.

Escherichia coli K-12 strain 285c contains a mutation in rpoD, the gene encoding the sigma subunit of RNA polymerase. The 70-kilodalton sigma polypeptide encoded by this allele is unstable, and this instability leads to temperature-sensitive growth. We describe the isolation and characterization of four temperature-resistant pseudorevertants of 285c that can grow at high temperature. Each of these revertants increased the stability of the sigma 70 mutant protein. The map position of the suppressor mutations was close to that of the rpoH (htpR) gene. A multicopy plasmid containing the intact rpoH gene restored the temperature-sensitive phenotype. Marker rescue experiments established the positions of three of the alleles within the rpoH gene. One mutation has been sequenced and causes a leucine-to-tryptophan change 7 amino acids from the carboxyl terminus of the rpoH gene product.     

Iron uptake in pseudorevertants of Escherichia coli K-12 mutants with multiple defects in the enterochelin system

Iron uptake in pseudorevertants of Escherichia coli K-12 strains which lack the ability to synthesize enterochelin, 2,3-dihydroxybenzoate, and the ferrienterochelin receptor protein was characterized. In four independent pseudorevertants, the suppressor mutations which permitted growth in iron-poor environments appeared to be located in ompB, the regulatory locus for the porin proteins. Unlike wild-type cells, the pseudorevertants were unable to utilize ferrienterochelin and could acquire iron from citrate without induction by prior growth in citrate. The energy requirements of the pseudorevertant system appeared to be identical to those of the enterochelin system. Evidence that loss of the porin proteins results in the secretion by the pseudorevertants of a molecule with siderophore activity is presented; this siderophore is able to remove iron from the non-biological iron chelators nitrilotriacetic acid and , -dipyridyl but not from the siderophores ferrichrome and enterochelin.     

Combinatorial mutagenesis and pseudorevertant analysis to characterize regions in loop E of the CP47 protein in Synechocystis sp. PCC 6803.

Deletion of the I265-F268 and T271-K277 regions in the large lumenally exposed loop of the CP47 protein are known to lead to a loss of photoautotrophic growth. Here, these regions have been investigated by combinatorial mutagenesis and pseudorevertant mapping. No single amino-acid residue in the I265-F268 region was found to be critical for function, but a large hydrophobic residue at position 267 and preferentially an aromatic residue at position 268 appeared to be required for photoautotrophic growth. Starting from an obligate photoheterotrophic mutant lacking the T271-K277 region, photoautotrophic pseudorevertants were generated with short in-frame tandem repeats near the site of the original deletion, partially or fully restoring the length of the original protein. These pseudorevertants were sensitive to oxygen indicating that the T271-K277 region may provide PS II stability and/or protection against oxygen-dependent photoinactivation. Pseudorevertants with much improved photoautotrophic growth were also generated for one of the combinatorial mutants in the I265-F268 region. Surprisingly, the secondary mutations in these pseudorevertants mapped to the ferrochelatase gene. We speculate that the secondary mutation in ferrochelatase gene resulted in altered ferrochelatase activity. Decreased heme (phycobilin) biosynthesis and/or increased chlorophyll biosynthesis could then lead to improved PS II performance of the combinatorial CP47 mutant.     

Photosystem II assembly in CP47 mutant of Synechocystis sp. PCC 6803 is dependent on the level of chlorophyll precursors regulated by ferrochelatase

Accumulation of chlorophyll and expression of the chlorophyll (Chl)-binding CP47 protein that serves as the core antenna of photosystem II are indispensable for the assembly of a functional photosystem II. We have characterized the CP47 mutant with an impaired photosystem II assembly and its two spontaneous pseudorevertants with their much improved photoautotrophic growth. The complementing mutations in these pseudorevertants were previously mapped to the ferrochelatase gene (1). We demonstrated that complementing mutations dramatically decrease ferrochelatase activity in pseudorevertants and that this decrease is responsible for their improved photoautotrophic growth. Photoautotrophic growth of the CP47 mutant was also restored by in vivo inhibition of ferrochelatase by a specific inhibitor. The decrease in ferrochelatase activity in pseudorevertants was followed by increased steady-state levels of Chl precursors and Chl, leading to CP47 accumulation and photosystem II assembly. Similarly, supplementation of the CP47 mutant with the Chl precursor Mg-protoporphyrin IX increased the number of active photosystem-II centers, suggesting that synthesis of the mutated CP47 protein is enhanced by an increased Chl availability in the cell. The probable role of ferrochelatase in the regulation of Chl biosynthesis is discussed.     

Pseudoreversion of lactose operator-constitutive mutants.

A set of pseudorevertants of lactose operator-constitutive (lacOc) mutant has been obtained. Analysis of a subset of these pseudorevertants indicates that, in some cases, the secondary mutation alters the lactose repressor (lacl gene product), whereas in others it seems to have occurred in the lactose operator (lacO) itself. Of the lacl gene mutations, the lacl8 mutation, already known to suppress all lacOc mutations nonspecifically, was recovered by a selection technique developed for this study. However, two additional lacl gene mutants were selected which appear to suppress lacOc sequences in a more-or-less specific fashion; repressor interaction with some operator sequences is facilitated, whereas the binding with lacO+ and others is attenuated concomitantly.     

Phenotypic Interactions among Mutations in a Thermus thermophilus 16S rRNA Gene Detected with Genetic Selections and Experimental Evolution

During protein synthesis, the ribosome undergoes conformational transitions between functional states, requiring communication between distant structural elements of the ribosome. Despite advances in ribosome structural biology, identifying the protein and rRNA residues governing these transitions remains a significant challenge. Such residues can potentially be identified genetically, given the predicted deleterious effects of mutations stabilizing the ribosome in discrete conformations and the expected ameliorating effects of second-site compensatory mutations. In this study, we employed genetic selections and experimental evolution to identify interacting mutations in the ribosome of the thermophilic bacterium Thermus thermophilus. By direct genetic selections, we identified mutations in 16S rRNA conferring a streptomycin dependence phenotype and from these derived second-site suppressor mutations relieving dependence. Using experimental evolution of streptomycin-independent pseudorevertants, we identified additional compensating mutations. Similar mutations could be evolved from slow-growing streptomycin-resistant mutants. While some mutations arose close to the site of the original mutation in the three-dimensional structure of the 30S ribosomal subunit and probably act directly by compensating for local structural distortions, the locations of others are consistent with long-range communication between specific structural elements within the ribosome.     

Interactions between chemotaxis genes and flagellar genes in Escherichia coli

Escherichia coli mutants defective in cheY and cheZ function are motile but generally nonchemotactic; cheY mutants have an extreme counterclockwise bias in flagellar rotation, whereas cheZ mutants have a clockwise rotational bias. Chemotactic pseudorevertants of cheY and cheZ mutants were isolated on semisolid agar and examined for second-site suppressors in other chemotaxis-related loci. Approximately 15% of the cheZ revertants and over 95% of the cheY revertants contained compensatory mutations in the flaA or flaB locus. When transferred to an otherwise wild-type background, most of these suppressor mutations resulted in a generally nonchemotactic phenotype: suppressors of cheY caused a clockwise rotational bias; suppressors of cheZ produced a counterclockwise rotational bias. Chemotactic double mutants containing a che and a fla mutation invariably exhibited flagellar rotation patterns in between the opposing extremes characteristic of the component mutations. This additive effect on flagellar rotation resulted in essentially wild-type swimming behavior and is probably the major basis of suppressor action. However, suppression effects were also allele specific, suggesting that the cheY and cheZ gene products interact directly with the flaA and flaB products. These interactions may be instrumental in establishing the unstimulated swimming pattern of E. coli.     

Isolation and characterization of dnaJ null mutants of Escherichia coli.

Bacteriophage lambda requires the lambda O and P proteins for its DNA replication. The rest of the replication proteins are provided by the Escherichia coli host. Some of these host proteins, such as DnaK, DnaJ, and GrpE, are heat shock proteins. Certain mutations in the dnaK, dnaJ, or grpE gene block lambda growth at all temperatures and E. coli growth above 43 degrees C. We have isolated bacterial mutants that were shown by Southern analysis to contain a defective, mini-Tn10 transposon inserted into either of two locations and in both orientations within the dnaJ gene. We have shown that these dnaJ-insertion mutants did not grow as well as the wild type at temperatures above 30 degrees C, although they blocked lambda DNA replication at all temperatures. The dnaJ-insertion mutants formed progressively smaller colonies at higher temperatures, up to 42 degrees C, and did not form colonies at 43 degrees C. The accumulation of frequent, uncharacterized suppressor mutations allowed these insertion mutants to grow better at all temperatures and to form colonies at 43 degrees C. None of these suppressor mutations restored the ability of the host to propagate phage lambda. Radioactive labeling of proteins synthesized in vivo followed by immunoprecipitation or immunoblotting with anti-DnaJ antibodies demonstrated that no DnaJ protein could be detected in these mutants. Labeling studies at different temperatures demonstrated that these dnaJ-insertion mutations resulted in altered kinetics of heat shock protein synthesis. An additional eight dnaJ mutant isolates, selected spontaneously on the basis of blocking phage lambda growth at 42 degrees C, were shown not to synthesize DnaJ protein as well. Three of these eight spontaneous mutants had gross DNA alterations in the dnaJ gene. Our data provide evidence that the DnaJ protein is not absolutely essential for E. coli growth at temperatures up to 42 degrees C under standard laboratory conditions but is essential for growth at 43 degrees C. However, the accumulation of extragenic suppressors is necessary for rapid bacterial growth at higher temperatures.     

Genetic Interactions among Chlamydomonas Reinhardtii Mutations That Confer Resistance to anti-Microtubule Herbicides

We previously described two types of genetic interactions among recessive mutations in the APM1 and APM2 loci of Chlamydomonas reinhardtii that may reflect a physical association of the gene products or their involvement in a common structure/process: (1) allele-specific synthetic lethality, and (2) unlinked noncomplementation, or dominant enhancement. To further investigate these interactions, we isolated revertants in which the heat sensitivity caused by the apm2-1 mutation is lost. The heat-insensitive revertants were either fully or partially suppressed for the drug-resistance caused by the apm2-1 allele. In recombination tests the revertants behaved as if the suppressing mutation mapped within the APM2 locus; the partial suppressors of apm2-1 herbicide resistance failed to complement apm2-1, leading to the conclusion that they were likely to be intragenic pseudorevertants. The apm2-1 partial suppressor mutations reversed apm1-apm2-1 synthetic lethality in an allele-specific manner with respect both to apm1- alleles and apm2-1 suppressor mutations. Those apm1- apm2-1rev strains that regained viability also regained heat sensitivity characteristic of the original apm2-1 mutation, even though the apm2-1 suppressor strains were fully heat-insensitive. The Hs+ phenotypes of apm2-1 partial suppressors were also reversed by treatment with the microtubule-stabilizing agent deuterium oxide (D2O). In addition to the above interactions, we observed interallelic complementation and phenotypic enhancement of temperature conditionality among apm1- alleles. Evidence of a role for the products of the two genes in microtubule-based processes was obtained from studying flagellar assembly in apm1- and apm2- mutants.     

An extreme clockwise switch bias mutation in fliG of Salmonella typhimurium and its suppression by slow-motile mutations in motA and motB.

Pseudorevertants (second-site suppressor mutants) were isolated from a set of parental mutants of Salmonella with defects in the flagellar switch genes fliG and fliM. Most of the suppressing mutations lay in flagellar region IIIb of the chromosome. One fliG mutant, SJW2811, gave rise to a large number of suppressor mutations in the motility genes motA and motB, which are in flagellar region II. SJW2811, which has a three-amino-acid deletion (delta Pro-Ala-Ala) at positions 169 to 171 of FliG, had an extreme clockwise motor bias that produced inverse smooth swimming (i.e., swimming by means of clockwise rotation of a hydrodynamically induced right-handed helical bundle), and formed Mot(-)-like colonies on semisolid medium. Unlike previously reported inverse-swimming mutants, it did not show a chemotactic response to serine, and it remained inverse even in a delta che background; thus, its switch is locked in the clockwise state. The location of the mutation further underscores the conclusion from a previous study of spontaneous missense mutants (V. M. Irikura, M. Kihara, S. Yamaguchi, H. Sockett, and R. M. Macnab, J. Bacteriol. 175:802-810, 1993) that a relatively localized region in the central part of the FliG sequence is critically important for switching. All of the second-site mutations in motA and motB caused some impairment of motility, both in the pseudorevertants and in a wild-type fliG background. The mechanism of suppression of the fliG mutation by the mot mutations is complex, involving destabilization of the right-handed flagellar bundle as a result of reduced motor speed. The mutations in the MotA and MotB sequences were clustered to a considerable degree as follows: in transmembrane helices 3 and 4 of MotA and the sole transmembrane helix of MotB, at helix-membrane interfaces, in the cytoplasmic domains of MotA, and in the vicinity of the peptidoglycan binding region of the periplasmic domain of MotB. The potential importance of Lys28 and Asp33 of the MotB sequence for proton delivery to the site of torque generation is discussed.