Analysis of rpsD mutations in Escherichia coli. I. Comparison of mutants with various alterations in ribosomal protein S4.

Summary Streptomycin-independent revertants were selected from streptomycin-dependent mutants. Twenty-five out of 150 such revertants were temperature sensitive. Ribosomal proteins from 18 temperature-sensitive and 10 temperature-insensitive revertants were analysed by SDS-polyacrylamide gel electrophoresis. Seventeen of the former but none of the latter category showed an alteration of protein S4. The mutated rpsD allele of 6 temperature-sensitive revertants was transduced into a rpsL ⁺ strain. In all cases an increased suppressibility of T4 amber phages was observed. Such suppressibility was not observed in the original rpsD, rpsL strains. All 18 temperature-sensitive mutants were disturbed in the processing of 17s to 16s RNA at non-permissive temperature and the accumulated 17s RNA was degraded. Temperature-insensitive rpsD revertants could be isolated, which had gained a second alteration in S4. Such revertants, which had lost the temperature-sensitive property, were also unable to suppress growth of T4 amber phages.It is concluded that temperature-sensitive growth, inability to process 17s RNA and to assemble 30S ribosomes at non-permissive temperature as well as increased translational ambiguity are highly correlated properties in rpsD mutants.     

SwoHp, a nucleoside diphosphate kinase, is essential in Aspergillus nidulans

The temperature-sensitive swoH1 mutant of Aspergillus nidulans was previously identified in a screen for mutants with defects in polar growth. In the present work, we found that the swoH1 mutant swelled, lysed, and did not produce conidia during extended incubation at the restrictive temperature. When shifted from the permissive to the restrictive temperature, swoH1 showed the temperature-sensitive swelling phenotype only after 8 h at the higher temperature. The swoH gene was mapped to chromosome II and cloned by complementation of the temperature-sensitive phenotype. The sequence showed that swoH encodes a homologue of nucleoside diphosphate kinases (NDKs) from other organisms. Deletion experiments showed that the swoH gene is essential. A hemagglutinin-SwoHp fusion complemented the mutant phenotype, and the purified fusion protein possessed phosphate transferase activity in thin-layer chromatography assays. Sequencing of the mutant allele showed a predicted V83F change. Structural modeling suggested that the swoH1 mutation would lead to perturbation of the NDK active site. Crude cell extracts from the swoH1 mutant grown at the permissive temperature had ~20% of the NDK activity seen in the wild type and did not show any decrease in activity when assayed at higher temperatures. Though the data are not conclusive, the lack of temperature-sensitive NDK activity in the swoH1 mutant raises the intriguing possibility that the SwoH NDK is required for growth at elevated temperatures rather than for polarity maintenance.     

Alteration in the contents of unsaturated fatty acids in dnaA mutants of Escherichia coli

DnaA protein, the initiator of chromosomal DNA replication in Escherichia coli , has a high affinity for acidic phospholipids containing unsaturated fatty acids. We have examined here the fatty acid composition of phospholipids in dnaA mutants. A temperature-sensitive dnaA46 mutant showed a lower level of unsaturation of fatty acids (ratio of unsaturated to saturated fatty acids) at 42°C (non-permissive temperature) and at 37°C (semi-permissive temperature), but not at 28°C (permissive temperature), compared with the wild-type strain. Plasmid complementation analysis revealed that the dnaA46 mutation is responsible for the phenotype. Other temperature-sensitive dnaA mutants showed similar results. On the other hand, a cold-sensitive dnaAcos mutant, in which overinitiation of DNA replication occurs at low temperature (28°C), showed a higher level of unsaturation of fatty acids at 28°C. Based on these observations, we discuss the role of phospholipids in the regulation of the activity of DnaA protein.     

Transcriptional activity and chromatin structural changes in a temperature-sensitive mutant of BHK cells blocked in early G1.

AF8, a temperature-sensitive mutant of BHK $\text{21}\text{13}$ cells, has been shown to arrest at the non-permissive temperature in the G1 phase of the cell cycle. When AF8 cells are released from density-dependent arrest of growth by trypsinization and replating at lower density, 60–80% of the cells enter DNA synthesis and divide at the permissive temperature (33 °C), while only 20% enter DNA synthesis at the non-permissive temperature (39.5 °C). The temperature-sensitive block has been localized 4 to 8 h before the onset of DNA synthesis which begins at 12 h after stimulation. Two biochemical events of the prereplicative phase have been temporally related to this temperature-sensitive block. RNA synthesis as measured in isolated nuclei increases initially at both temperatures, then levels off and declines to control levels at 39.5 °C while continuing to increase at 33 °C. Parallel changes are found in circular dichroism spectra and ethidium bromide binding capacity of isolated chromatin. The results suggest that these biochemical changes are involved in the regulation of the prereplicative phase and the subsequent entrance of cells into DNA synthesis.     

A streptomycin-resistant Escherichia coli mutant with ribosomes temperature-sensitive in the suppression of a nonsense codon.

Summary Cell free extracts from a streptomycin-resistant E. coli mutant which is also temperature-sensitive for Q phage were studied for suppression of a nonsense mutation at various temperatures. The streptomycin-resistant ribosomes of the mutant were found to be temperature-sensitive in suppression of an amber mutation in f2 phage coat protein while retaining the ability to synthesize proteins at an elevated temperature (42° C). The restriction of amber suppression at 42° C is assumed to be related to an alteration in the ribosomal protein S12 of the streptomycin-resistant mutant which also causes a change in its electrophoretic mobility.     

The role of 5-S RNA in temperature-sensitive ribosomal RNA maturation.

The synthesis of 5-S RNA was found to be unchanged at both the permissive (33.5 degrees C) and non-permissive (38.5 degrees C) temperatures in a temperature-sensitive Baby Hamster Kidney cell line (BHK 21 ts 422 E) as measured relative to synthesis of 18-S rRNA. The 5-S RNA is shown to be associated with nucleolar ribonucleoprotein particles even though rRNA processing does not yield a functional 28-S rRNA at the non-permissive temperature. The amount of 5-S RNA found associated with the 80-S ribonucleoprotein particles was the same at the permissive and non-permissive temperatures, indicating that an aberrant 5-S RNA contribution to rRNA processing is not a primary cause for the temperature-sensitive lesion of rRNA maturation in this mutant cell line. The amount of 5-S RNA in nucleolar 80-S RNA particles indicated that the association of 5-S RNA with the rRNA precursor particle occurs before the cleavage step at which 32-S precursor RNA is produced.     

On the molecular basis of the thermal sensitivity of an Escherichia coli topA mutant.

Studies of two temperature-sensitive Escherichia coli topA strains AS17 and BR83, both of which were supposed to carry a topA amber mutation and a temperature-sensitive supD43,74 amber-suppressor, led to conflicting results regarding the essentiality of DNA topoisomerase I in cells grown in media of low osmolarity. We have therefore reexamined the molecular basis of the temperature sensitivity of strain AS17. We find that the supD allele in this strain had lost its temperature sensitivity. The temperature sensitivity of the strain, in media of all osmolarity, results from the synthesis of a mutant DNA topoisomerase I that is itself temperature-sensitive. Nucleotide sequencing of the AS17 topA allele and studies of its expected cellular product show that the mutant enzyme is not as active as its wild-type parent even at 30 degrees C, a permissive temperature for the strain, and its activity relative to the wild-type enzyme is further reduced at 42 degrees C, a nonpermissive temperature. Our results thus implicate an indispensable role of DNA topoisomerase I in E. coli cells grown in media of any osmolarity.     

Involvement of Gene 49 in Recombination of Bacteriophage T4

The role of T4 gene 49 in recombination was investigated using its conditional-lethal amber (am) and temperature-sensitive (ts) mutants. When measured in genetic tests, defects in gene 49 produced a recombination-deficient phenotype. However, DNA synthesized in cells infected with a ts mutant (tsC9) at a nonpermissive temperature appeared to be in a recombinogenic state: after restitution of gene function by shifting to a permissive temperature, the recombinant frequency among progeny increased rapidly even when DNA replication was blocked by an inhibitor. Growth of a gene 49-defective mutant was suppressed by an additional mutation in gene uvsX, but recombination between rII markers was not.     

A temperature-sensitive Chinese hamster ovary cell mutant pleiotropically defective in protein export

We have developed a new selection procedure for mammalian cell mutants defective in protein export by the use of diphtheria toxin, and devised a new screening method for defective protein secretion using nitrocellulose membranes. By the combination of these procedures, we have isolated a temperature-sensitive mutant clone of Chinese hamster ovary cells which shows a pleiotropic defect in protein export. This mutant, designated DS28-6, is temperature-sensitive for growth. Secretion of a series of proteins is markedly inhibited at the non-permissive temperature. These proteins seem to be normally synthesized and accumulated within the cell at the non-permissive temperature and secreted upon shift down to the permissive temperature. When this mutant is infected with vesicular stomatitis virus, oligosaccharide processing of G-protein is arrested at an endoglycosidase-H-sensitive stage at the non-permissive temperature. The lesion of this mutant appears to be in the endoplasmic reticulum or the cis Golgi or both.     

Genetic control of DNA initiation in Escherichia coli

We describe the isolation, and properties of a mutant (CT28) of Escherichia coli with a temperature-sensitive defect in DNA initiation that is reversible. The mutation (dna-28) responsible for this defect is shown to be located in the same region of the map as the dnaC group of DNA initiation mutants.A terminalized culture of CT28 initiates DNA synthesis synchronously immediately upon lowering the temperature, and will do so in the presence of chloram-phenicol.During prolonged incubation at the non-permissive temperature, the cells accumulate a capacity to initiate multiple rounds of replication per chromosome.The variation in the susceptibility of the argH^? and thyA^? alleles to reversion by pulse mutagenesis with nitrosoguanidine during a synchronous round of DNA replication, suggests that this round of replication is bidirectional and commences from an origin in the vicinity of 60 to 65 minutes.CT28 contains two temperature-sensitive mutations. These have been mapped and separated into two derivative strains. One of these, CT28-3b, carries the dna-28 mutation of the C locus, and like the parental double mutant is reversibly temperature-sensitive for an initiation function; but it is more temperature-sensitive than either the double mutant or the other single mutant derivative, CT28-1. The other, CT28-1, is not defective in DNA replication or initiation of replication at the non-permissive temperature.     

Transmission of bacteriophage T4 amber mutants. I. Temperature sensitivity of gene 26 T4 phage mutant amN131 multiplication in Escherichia coli B cells]

When studying the single cycle of the multiplication of gene 26 mutant amN131 of phage T4, like in temperature shift experiments, the yield of this mutant in non-permissive host depends greatly on the temperature. The burts size of phage in Escherichia coli B is found to be 3.3 phage particles at 25 degrees C, 1.6 at 30 degrees C, 0.051 at 37 degrees C and 0.0007 at 41 degrees C. In the case of permissive host (E. coli CR-63) the burst size per cell decreases from 158 to 49 phage particles at the same temperature interval. The results of the single-burst experiments indicate, that when the incubation temperature increases, the number of E. coli B cells, in which the phage particles maturate, also decreases. It results in the dependence of the transmission coefficient value on the temperature. The transmission coefficient in the conditions favourable for the maturation of the phage is found to be 0.80. It is shown by several methods that the temperature sensitivity of the multiplication of the mutant amN131 in bacterial cells is entirely due to amber mutation in genome of the phage. Therefore the amber mutants having high temperature sensitivity when maturating in non-permissive host cells exist among ordinary amber mutants of phage T4.     

Isolation and analysis of a mammalian temperature-sensitive mutant defective in G2 functions

A temperature-sensitive (ts) mutant, designated tsFT210, was isolated from a mouse mammary carcinoma cell line, FM3A. The tsFT210 cells grew normally at 33 degrees C (permissive temperature), but more than 80% of the cells were arrested at the G2 phase at 39 degrees C (non-permissive temperature) as revealed by flow-microfluorimetric analysis. DNA replication and synthesis of other macromolecules by this mutant seemed to be normal at 39 degrees C for at least 10 h. However, in this mutant, hyperphosphorylation of H1 histone from the G2 to M phase, which occurs in the normal cell cycle, could not be detected at the non-permissive temperature. This suggests that a gene product which is temperature-sensitive in tsFT210 cells is necessary for hyperphosphorylation of H1 histone and that this gene product may be related to chromosome condensation.     

Temperature-dependent and amber copy mutants of plasmid R1drd-19 in Escherichia coli.

The isolation of conditional mutants with an altered copy number of the R plasmid R1drd-19 is described. Temperature-dependent as well as amber-suppressible mutants were found. These mutant plasmids have been named pKN301 and pKN303, respectively. Both types of mutations reside on the R plasmid. No difference in molecular weight could be detected by neutral sucrose gradient centrifugation for any of the mutant plasmids when compared with the wild-type plasmid. The number of copies of the plasmids was determined by measurement of the specific activity of the R plasmid-mediated β-lactamase and by measurement of covalently closed circular (CCC) DNA in alkaline sucrose gradients and dye-CsCl density gradients. Below 34 °C the temperature-dependent mutant, pKN301, had the same copy number as the wild type, while this was four times that of the wild type above 37 °C. The amber mutant pKN303 had a copy number indistinguishable from that of the wild-type plasmid in a strain containing a strong amber suppressor and a copy number about five times that of the wild-type plasmid in a strain lacking an amber suppressor. In a strain containing a temperature-sensitive amber suppressor, the amber mutant's copy number increased with the decrease in amber suppressor activity. Thus, the existence of the temperature-dependent and the amber-suppressible R-plasmid copy mutants indicates that the system that controls the replication of plasmid R1drd-19 contains an element with a negative function and that this element is a protein.     

Reversal by sodium chloride of envelope protein changes related to DNA replication and cell division of Escherichia coli

Further evidence is presented here for previously reported connections between the syntheses of two envelope proteins X and Y, cell division and DNA replication, respectively. On addition of 1% NaCl to an Escherichia coli temperature-sensitive mutant at 41 °C (non-permissive temperature) the phenotype, inability to synthesize DNA but continued ability to divide at 41 °C in the absence of NaCl, becomes wild-type. The syntheses of proteins X and Y also are converted to the wild-type pattern by NaCl. Furthermore, inhibition of DNA synthesis by thymidine starvation at 41 °C in the presence of NaCl changes the cell envelope proteins as with the wild-type, in contrast to altered syntheses in the absence of NaCl. The effect of nalidixic acid on the mutant and a recA strain are also studied for changes in envelope proteins. All of these changes are consistent with the originally proposed relationships.