Isolation and Characterization of an Escherichia coli K-12 Mutant with a Temperature-Sensitive RecA− Phenotype

A mutation that causes a temperature-sensitive RecA(-) phenotype was identified in a derivative of a PolA(-) strain that failed to grow at high temperature. The mutant allele (recA200) was shown to be linked to cysC, conferred a sharply temperature-sensitive, ultraviolet-sensitive Rec(-) phenotype in the range 35 to 42 C, and in crosses failed to show complementation at 42 C with Hfr's that transferred recA(-). Double mutants that carried both recA200 and polA were examined for ability to grow and synthesize DNA at restrictive temperatures.     

A Temperature-Sensitive Chlorophyll b-Deficient Mutant of Sweetclover (Melilotus alba)

The ch4 mutant of sweetclover (Melilotus alba) has previously been demonstrated to be partially deficient in chlorophyll and to have a higher ratio of chlorophyll a to b than normal plants. We were able to substantiate these findings when plants were grown at 23°C and lower (permissive temperatures). However, when grown at 26°C (nonpermissive temperature) the plants produced small yellow leaves which exhibited one-twentieth the chlorophyll content of normal plants. Affected leaves did not increase their chlorophyll content when plants were incubated at permissive temperatures, but leaves which developed at the lower temperature contained increased amounts of chlorophyll. Similarly, only new leaves, not previously grown leaves, exhibited the yellow phenotype when the mutant plant was shifted from the permissive temperature to the nonpermissive temperature. Ribulose 1,5-bisphosphate carboxylase activity was decreased by half, relative to normal plants, in the mutant plants grown at the nonpermissive temperature, indicating that general protein synthesis was not greatly impaired and that the effect of the mutation was perhaps specific for chlorophyll content. HPLC analysis indicated that carotenoid content was not diminished to the same extent as chlorophyll and we have determined that the thylakoid protein kinase is not altered, as is the case for other chlorophyll b-deficient mutants. Experiments suggest that changes in photoperiod may be able to modulate the effect of temperature.     

Temperature-Sensitive Behavior of the Hemagglutinin in a Temperature-Sensitive Mutant Virion of Sindbis

The hemagglutinating ability of a temperature-sensitive mutant virion was reversibly lost when the temperature of hemagglutination was increased from 27 to 37 C.     

Single Site Suppressors of a Fission Yeast Temperature-Sensitive Mutant in cdc48 Identified by Whole Genome Sequencing

The protein called p97 in mammals and Cdc48 in budding and fission yeast is a homo-hexameric, ring-shaped, ubiquitin-dependent ATPase complex involved in a range of cellular functions, including protein degradation, vesicle fusion, DNA repair, and cell division. The cdc48⁺ gene is essential for viability in fission yeast, and point mutations in the human orthologue have been linked to disease. To analyze the function of p97/Cdc48 further, we performed a screen for cold-sensitive suppressors of the temperature-sensitive cdc48-353 fission yeast strain. In total, 29 independent pseudo revertants that had lost the temperature-sensitive growth defect of the cdc48-353 strain were isolated. Of these, 28 had instead acquired a cold-sensitive phenotype. Since the suppressors were all spontaneous mutants, and not the result of mutagenesis induced by chemicals or UV irradiation, we reasoned that the genome sequences of the 29 independent cdc48-353 suppressors were most likely identical with the exception of the acquired suppressor mutations. This prompted us to test if a whole genome sequencing approach would allow us to map the mutations. Indeed genome sequencing unambiguously revealed that the cold-sensitive suppressors were all second site intragenic cdc48 mutants. Projecting these onto the Cdc48 structure revealed that while the original temperature-sensitive G338D mutation is positioned near the central pore in the hexameric ring, the suppressor mutations locate to subunit-subunit and inter-domain boundaries. This suggests that Cdc48-353 is structurally compromized at the restrictive temperature, but re-established in the suppressor mutants. The last suppressor was an extragenic frame shift mutation in the ufd1 gene, which encodes a known Cdc48 co-factor. In conclusion, we show, using a novel whole genome sequencing approach, that Cdc48-353 is structurally compromized at the restrictive temperature, but stabilized in the suppressors.     

Mutant of Bacillus subtilis with a Temperature-Sensitive Autolytic Amidase

A procedure incorporating a petri plate assay for autolysins has been developed for the systematic isolation of mutants with a temperature-sensitive autolytic amidase. We suggest maa as the name for the gene for this enzyme. One such mutant has been characterized as having a heat-sensitive amidase in a variety of studies with both crude autolysin preparations and purified amidase solutions.     

A Temperature-Sensitive Mutant in TETRAHYMENA PYRIFORMIS, Syngen 1

After treatment with nitrosoguanidine a mutation to temperature sensitivity was obtained in Tetrahymena pyriformis, syngen 1. The trait is controlled by a recessive allele, ts, at a locus linked to serotype locus T. ts is completely recessive, unlike any other allele studied in this organism, and the heterozygotes do not show vegetative assortment. The cross which revealed the linkage of ts and T failed to show evidence of the linkage of mt (mating type) and E-1 (esterase-1) which has been demonstrated in other crosses (Allen 1964; Doerder 1972), but revealed a third case of linkage, involving mt and TO (tetrazolium oxidase). Taken together, these results are presumptive evidence for large interstrain differences in recombination properties within syngen 1.     

Division Site Regulation in a Temperature-Sensitive Mutant of Bacillus subtilis

Division site location was measured in Bacillus subtilis clones grown from spores at 30 and 45 C. Regulation of division location is lost in mutant 168ts-151 at 45 C.     

Temperature-Sensitive Simian Virus 40 Mutant Defective in a Late Function

A temperature-sensitive simian virus 40 (SV40) mutant, tsTNG-1, has been isolated from nitrosoguanidine-treated and SV40-infected African green monkey kidney (CV-1) cultures. Replication of virus at the nonpermissive temperature (38.7 C) was 3,000-fold less than at the permissive temperature (33.5 C). Plaque formation by SV40tsTNG-1 deoxyribonucleic acid (DNA) on CV-1 monolayers occurred normally at 33.5 C but was grossly inhibited at 38.7 C. The time at which virus replication was blocked at 38.7 C was determined by temperature-shift experiments. In shift-up experiments, cultures infected for various times at 33.5 C were shifted to 38.7 C. In shift-down experiments, cultures infected for various times at 38.7 C were shifted to 33.5 C. All cultures were harvested at 96 hr postinfection (PI). No virus growth occurred when the shift-up occurred before 40 hr PI. Maximum virus yields were obtained at 96 hr PI when the shift-down occurred at 66 hr, but only about 15% of the maximum yield was obtained when the shift-down occurred at 76 hr PI. These results indicate that SV40tsTNG-1 contains a conditional lethal mutation in a late viral gene function. Mutant SV40tsTNG-1 synthesized T antigen, viral capsid antigens, and viral DNA, and induced thymidine kinase activity at either 33.5 or 38.7 C. The properties of the SV40 DNA synthesized in mutant-infected CV-1 cells at 33.5 or 38.7 C were very similar to those of SV40 DNA made in parental virus-infected cells, as determined by nitrocellulose column chromatography, cesium-chloride-ethidium bromide equilibrium centrifugation, and by velocity centrifugation in neutral sucrose gradients. Mutant SV40tsTNG-1 enhanced cellular DNA synthesis in primary cultures of mouse kidney cells at 33.5 and 38.7 C and also transformed mouse kidney cultures at 36.5 C. SV40tsTNG-1 was recovered from clonal lines of transformed cells after fusion with susceptible CV-1 cells and incubation of heterokaryons at 33.5 C, but not at 38.7 C.     

Temperature-Sensitive Initiation of Chromosome Replication in a Mutant of Escherichia coli

The properties of Escherichia coli mutant D2-47LT indicate that it is temperature-sensitive for a protein required for the initiation of chromosome replication. The results of several different experiments are consistent with this hypothesis, and no support was found for the alternate hypotheses tested. Although the strain is usually unable to initiate replication at 42 C, some of the initiation proteins are apparently synthesized at the restrictive temperature. This can cause initiation on partially replicated, but not completed, chromosomes. It appears that the temperature-sensitive protein is required for initiation on completed chromosomes.     

Isolation and Properties of a Temperature-Sensitive Sporulation Mutant of Bacillus subtilis

A thermosensitive sporulation mutant (t(s)-4) of Bacillus subtilis was isolated, and its morphological, physiological, and enzymatic properties were investigated. This mutant is able to grow equally well at 30 and 42 C, but is unable to sporulate at the higher temperature. Electron microscope studies have shown that the t(s)-4 mutant is blocked at stage zero of spore development. This was further confirmed by its inability to produce antibiotic when grown at the restrictive temperature and by the relatively low ribonucleic acid (RNA) and protein turnover during the stationary growth phase, characteristic for stage zero asporogenic mutants. At the permissive temperature, however, antibiotic production and RNA and protein turnover took place at the rate normally found in sporogenic strains of B. subtilis. The above properties were not altered in the parent strain when grown at either 30 or 42 C. By shifting cultures of the t(s)-4 mutant from 30 to 42 C and from 42 to 30 C at different stages of growth, we have been further able to show that the event affected at the high temperature takes place at a very early stage of spore development. As a consequence of this early block in the sporulation process, the t(s)-4 mutant grown at 42 C became defective in the late spore-specific enzymes involved in the biosynthesis of dipicolinic acid. This study suggests that the sporulation process is mediated by a regulatory protein which is altered in the thermosensitive mutant when grown at the restrictive temperature. As a result of this alteration, a pleiotropic phenotype is produced which has lost the ability to catalyze the late biochemical reactions required for spore formation.     

Ultrastructure of a Temperature-Sensitive Rod− Mutant of Bacillus subtilis

Mutant 168ts-200B, resulting from nitrosoguanidine treatment of Bacillus subtilis 168 (trp(-) C2), exhibits a rod-to-sphere morphogenetic interconversion when the incubation temperature is 30 or 45 C, respectively. Ultrathin sections of rods grown at 30 C, after glutaraldehyde-osmium uranium-lead fixation and staining, show trilaminar cell walls with a well-developed underlying periplasm as in wild-type cells. However, the outer wall layer is irregular, and abnormal protrusions of wall material occur at the cross-walls. In contrast, cells growing at 45 C become rounded and are intersected randomly by irregular cross-walls which fail to split normally, resulting in large spherical masses. In these, the outer and inner wall layers and periplasm are lost, and the wall consists only of irregularly thickened and loosely organized middle layer. Wall ultrastructure is reversible in either direction as cell shape changes during temperature shifts. Mesosomes are rare and atypical at either temperature. It thus appears that cell wall ultrastructure is altered by the conditional (temperature-sensitive) mutation, and that loss of normal wall and submural organization is correlated with changes in cell size and shape as well as with inability to complete cell division. Preliminary studies after transformation of the mutant locus to another strain and growth at 45 C showed an increase in mucopeptide, loss of wall teichoic acid, failure of phage adsorption, and identical ultrastructural changes. The site of expression of the basic defect-be it in wall, submural region, or membrane-is undetermined.     

Enhanced Mutability Associated with a Temperature-Sensitive Mutant of Vesicular Stomatitis Virus

Temperature-sensitive (ts) mutant tsD1 of vesicular stomatitis virus, New Jersey serotype, is the sole representative of complementation group D. Clones derived from this mutant exhibited three different phenotypes with respect to electrophoretic mobility of the G and N polypeptides of the virion in sodium dodecyl sulfate-polyacrylamide gel. Analysis of non-ts pseudorevertants showed that none of the three phenotypes was associated with the temperature sensitivity of mutant tsD1. Additional phenotypes, some also involving the NS polypeptide, appeared during sequential cloning, indicating that mutations were generated at high frequency during replication of tsD1. Furthermore, mutations altering the electrophoretic mobility of the G, N, NS, and M polypeptides were induced in heterologous viruses multiplying in the same cells as tsD1. These heterologous viruses included another complementing ts mutant of vesicular stomatitis virus New Jersey and ts mutants of vesicular stomatitis virus Indiana and Chandipura virus. Complete or incomplete virions of tsD1 appeared to be equally efficient inducers of mutations in heterologous viruses. Analysis of the progeny of a mixed infection of two complementing ts mutants of vesicular stomatitis virus New Jersey with electrophoretically distinguishable G, N, NS, and M proteins yielded no recombinants and excluded recombination as a factor in the generation of the electrophoretic mobility variants. In vitro translation of total cytoplasmic RNA from BHK cells indicated that post-translational processing was not responsible for the aberrant electrophoretic mobility of the N, NS, and M protein mutants. Aberrant glycosylation could account for three of four G protein mutants, however. Some clones of tsD1 had an N polypeptide which migrated faster in sodium dodecyl sulfate-polyacrylamide gel than did the wild type, suggesting that the polypeptide might be shorter by about 10 amino acids. Determination of the nucleotide sequence to about 200 residues from each terminus of the N gene of one of these clones, a revertant, and the wild-type parent revealed no changes compatible with synthesis of a shorter polypeptide by premature termination or late initiation of translation. The sequence data indicated, however, that the N-protein mutant and its revertant differed from the parental wild type in two of the 399 nucleotides determined. These sequencing results and the phenomenon of enhanced mutability associated with mutant tsD1 reveal that rapid and extensive evolution of the viral genome can occur during the course of normal cytolytic infection of cultured cells.     

Neuroblastoma Cell Fusion by a Temperature-Sensitive Mutant of Vesicular Stomatitis Virus

A temperature sensitive mutant of vesicular stomatitis virus which does not mature properly when grown at 39 degrees C promoted extensive fusion of murine neuroblastoma cells at this nonpermissive temperature. Polykaryocytes apparently formed as a result of fusion from within the cells that requires low doses of infectious virions for its promotion and is dependent on viral protein synthesis. Although 90% of infected N-18 neuroblastoma cells were fused by 15 h after infection, larger polykaryocytes continued to form, leading to an average of 28 nuclei per polykaryocyte as a result of polykaryocytes fusing to each other. Two neuroblastoma cell lines have been observed to undergo fusion, whereas three other cell lines (BHK-21, CHO, and 3T3) were incapable of forming polykaryocytes, suggesting that nervous system-derived cells are particularly susceptible to vesicular stomatitis virus-induced fusion. Although the normal assembly of the protein components of this virus is deficient at 39 degrees C, the G glycoprotein was inserted into the infected cell membranes at this temperature. Two lines of evidence suggest that the expression of G at the cell surface promotes this polykaryocyte formation: (i) inhibition of glycosylation, which may be involved in the migration of the G protein to the cellular plasma membranes, will inhibit the cell fusion reaction; (ii) addition of antiserum, directed toward the purified G glycoprotein, will also inhibit cell fusion.     

Temperature-Sensitive Initiation of Chromosome Replication in a Mutant of Bacillus subtilis

A mutant of Bacillus subtilis Ts37 has been isolated in which deoxyribonucleic acid (DNA) synthesis is inhibited at high temperature. The results presented here indicate that the process of initiation of DNA replication is temperature sensitive in this mutant. After shifting to 45 C, DNA increases 40 to 50% before synthesis ceases; an inhibition of protein synthesis permits an equivalent amount of DNA to be synthesized. A density shift experiment coupled with a marker frequency analysis shows that DNA synthesized at 45 C is highly enriched in the markers situated at the end of the chromosome. Transforming DNA extracted from a culture which has been incubated at 45 C exhibits the relative transforming efficiency for origin and terminus markers characteristic of completed chromosomes. After a shift back from 45 C to 30 C, reinitiation appears to occur always in the same region of the bacterial chromosome; in addition, replication as well as cell division is synchronized.     

Isolation and Characterization of a Temperature-Sensitive Circadian Clock Mutant of Neurospora Crassa

A new circadian clock mutant has been isolated in Neurospora crassa. This new mutation, called period-6 (prd-6), has two features novel to known clock mutations. First, the mutation is temperature sensitive. At restrictive temperatures (above 21°) the mutation shortens circadian period length from a wild-type value of 21.5 hr to 18 hr. At permissive temperatures (below 21°) the mutant has a 20.5-hr period length close to that of the wild-type strain. Second, the prd-6 mutation is epistatic to the previously isolated clock mutation period-2 (prd-2). This epistasis is unusual in that the prd-2 prd-6 double mutant strain has an 18-hr period length at both the restrictive and permissive temperatures. That is, the temperature-sensitive aspect of the phenotype of the prd-6 strain is lost in the prd-2 prd-6 double mutant strain. This suggests that the gene products of the prd-2 and prd-6 loci may interact physically and that the presence of a normal prd-2(+) protein is required for low temperature to ``rescue' the prd-6 mutant phenotype. These results, combined with our recent finding that prd-2 and some alleles of the frq gene show genetic synergy, suggest that it may be possible to establish a more comprehensive model of the Neurospora circadian clock.     

Characterization of Mutants of Escherichia coli Temperature-Sensitive for Ribonucleic Acid Regulation: an Unusual Phenotype Associated with a Phenylalanyl Transfer Ribonucleic Acid Synthetase Mutant

A mutant strain AA-522, temperature-sensitive for protein synthesis, was isolated from a stringent strain (CP-78) of Escherichia coli K-12. The mutant strain has a relaxed phenotype at the nonpermissive growth temperature. Protein synthesis stops completely at 42 C, whereas the rate of ribonucleic acid (RNA) synthesis is maintained at 20% of the 30 C rate. Sucrose-gradient centrifugation analysis of RNA-containing particles formed at 42 C indicated the presence of “relaxed particles.” These particles possess 16S and 23S RNA and are precursors to normal 50S and 30S ribosomal subunits. A search for the temperature-sensitive protein responsible for the halt in protein synthesis implicated phenylalanyl transfer RNA (tRNA) synthetase. Essentially no enzyme activity is detected in vitro at 30 or 40 C. Analysis of phenylalanyl tRNA synthetase activity in revertants of strain AA-522 indicated the presence of intragenic suppressor mutations. Revertants of strain AA-522 analyzed for the relaxed response at 42 C were all stringent; strain AA-522 was stringent at 30 C. These data indicate that a single mutation in phenylalanyl tRNA synthetase is responsible for both a block in protein synthesis and the relaxed phenotype at 42 C.