Application of temperature-sensitive mutants for single-cell protein production

Cell-division-cycle, temperature-sensitive mutants of Saccharomyces cerevisiae were investigated as a means of altering the morphological characteristics and subsequent physical properties of single-cell protein (SCP). Strain 4471, harboring mutation cdc 4, formed a visible complex mass at the nonpermissive temperature, after being grown at 30°C and then transferred to 37°C for 8 hr. Microscopic observation showed that the mother cell was unable to complete the budding process at the nonpermissive temperature, which caused the cells to enlarge. Viscosity measurements were used to establish and characterize optimum morphological changes in the yeast. The Maximum increase in viscosity occurred when cells were incubated at 30°C and then shifted to 37°C for 8 hr. Strain 4471 exhibited yield stress, whereas A364A did not. Maximum change in yield stress occurred when cells were shifted from 30 to 37°C for 8 hr. No significant loss of protein or RNA occurred in strain 4471, as compared to strain A364A, when incubated at the nonpermissive temperature.     

Alterations in glucose metabolism in chick embryo cells transformed by Rous sarcoma virus. Transformation-specific changes in the activities of key enzymes of the glycolytic and hexose monophosphate shunt pathways

Effects of transformation by Rous sarcoma virus of Schmidt-Ruppin strain on the activities of key enzymes of the glycolytic and the hexose monophosphate shunt pathways in chick-embryo cells were investigated. Activities of hexokinase, phosphofructokinase, pyruvate kinase, lactate dehydrogenase, and glucose-6-P dehydrogenase were increased about twofold in the transformed cells, but that of 6-P-gluconate dehydrogenase remained unaltered. The transformation-mediated increase in the activity of hexokinase was confined entirely to the bound form of the enzyme. Cells infected with a temperature-sensitive mutant (Ts-68) of Schmidt-Ruppin strain of Rous sarcoma virus showed the typical increase in the rate of 2-deoxyglucose uptake and the activities of hexokinase, phosphofructokinase, pyruvate kinase, and glucose-6-P dehydrogenase at the permissive temperature (37 °C), but when the infected cells were grown at the nonpermissive temperature (41 °C), the increases in the sugar uptake and activities of these enzymes were abolished. Unlike the regulatory enzymes, lactate dehydrogenase activity was increased at both the permissive and the nonpermissive temperatures.     

High-throughput enrichment of temperature-sensitive argininosuccinate synthetase for two-stage citrulline production in E. coli

Controlling metabolism of engineered microbes is important to modulate cell growth and production during a bioprocess. For example, external parameters such as light, chemical inducers, or temperature can act on metabolism of production strains by changing the abundance or activity of enzymes. Here, we created temperature-sensitive variants of an essential enzyme in arginine biosynthesis of Escherichia coli (argininosuccinate synthetase, ArgG) and used them to dynamically control citrulline overproduction and growth of E. coli. We show a method for high-throughput enrichment of temperature-sensitive ArgG variants with a fluorescent TIMER protein and flow cytometry. With 90 of the thus derived ArgG variants, we complemented an ArgG deletion strain showing that 90% of the strains exhibit temperature-sensitive growth and 69% of the strains are auxotrophic for arginine at 42 °C and prototrophic at 30 °C. The best temperature-sensitive ArgG variant enabled precise and tunable control of cell growth by temperature changes. Expressing this variant in a feedback-dysregulated E. coli strain allowed us to realize a two-stage bioprocess: a 33 °C growth-phase for biomass accumulation and a 39 °C stationary-phase for citrulline production. With this two-stage strategy, we produced 3 g/L citrulline during 45 h cultivation in a 1-L bioreactor. These results show that temperature-sensitive enzymes can be created en masse and that they may function as metabolic valves in engineered bacteria.     

Production of infectious particles at the nonpermissive temperature by a temperature-sensitive mutant of bacteriophage SH-133 specific forPseudomonas facilis

The preliminary characterization of a unique temperature-sensitive (ts) mutant of bacteriophage SH-133, designatedts18, is reported. The mutant showed a substantial reduction in the ability to form plaques at the nonpermissive temperature (32°C) when compared with its plaqueforming ability at the permissive temperature (27°C). However, the supernatant fromts18-infected cells grown at 32°C exhibited significant infectivity when assayed at 27°C, which indicates that the reduced titer ofts18 at 32°C is not due to its inability to form phage particles at that temperature. Phage particles produced at 32°C, but not at 27°C, were thermolabile when tested at 32°C. The thermolability of phage yields from cells mixedly infected at 32°C with increasing wild-type/ts18 input ratios was independent of the quantity of wild-type gene product per cell. Thermostable phage particles were yielded byts18-infected cells that received short pulses of permissive temperature during the latter part of the latent period. These data indicate that the defect of the mutant is due to the production of a nonstructural assembly protein that misfunctions when viral maturation proceeds at the nonpermissive temperature.     

Hormone-dependent terminal differentiation in vitro of chicken erythroleukemia cells transformed by ts mutants of avian erythroblastosis virus

Chicken erythroblast cell strains and a cell line transformed by ts mutants of avian erythroblastosis virus (AEV) terminally differentiate when shifted to the nonpermissive temperature (42°C). The differentiated cells resemble mature erythrocytes with respect to morphology and ultrastructure, expression of differentiation-specific cell-surface antigens, pattern of protein synthesis and hemoglobin content. Terminal differentiation is dependent on conditions favoring the differentiation of normal erythroid progenitor cells, including an erythropoietin-like factor. Colonies of ts AEV cells grown at 42°C in semisolid medium resemble erythrocyte colonies derived from normal erythroid progenitor cells. The colonies obtained were comparable in size or slightly larger than the late erythroid precursor (CFU-E) colonies. These results suggest that AEV-transformed cells are blocked at a stage of differentiation that is more advanced than that of the uninfected target cells. ts AEV cells are irreversibly committed to terminal differentiation within 20 to 30 hr after shift to 42°C.     

Temperature sensitivity of muscle and neuron differentiation in embryonic cell cultures from the Drosophila mutant, shibire.

The sex-linked temperature-sensitive mutation, shibire^ts1, which causes, at the restrictive temperature, adult paralysis and pleiotropic morphological defects in embryonic, larval, and pupal development, has been shown to exhibit temperature-sensitive inhibition of differentiation in embryonic cultures in vitro. When shi cultures were incubated at 30°C for 24 hr, both muscle and neuron differentiation were inhibited more than 90% compared to control shi cultures incubated at 20°C. Heat shift experiments showed that the temperature-sensitive periods for neuron and muscle differentiation occurred at 11 to 18 and 14 to 16 hr, respectively, where zero time was the initiation of gastrulation in donor embryos. Short heat pulses (4 and 8 hr) which extended into the temperature-sensitive period resulted in moderate inhibition of differentiation; greater inhibition occurred as the duration of the pulses increased. In contrast, heating wild-type Oregon-R cultures at 30°C for 24 hr did not inhibit muscle cell differentiation and inhibited neuron differentiation relatively little. The temperature-sensitive period in shibire for muscle differentiation occurred well after myoblast division, during the period of myocyte elongation, aggregation, and fusion, whereas that for neuron differentiation took place during a period of enzyme synthesis (acetylcholinesterase and choline acetyltransferase) and axon elongation. Thus, the shi temperature-sensitive gene product affects at least two different cell types, in vitro, at different times during differentiation.     

Temperature-sensitive mutants blocked in the folding or subunit assembly of the bacteriophage P22 tail spike protein: II. Active mutant proteins matured at 30 °C

Little is known of the molecular mechanisms by which temperature-sensitive mutations interfere with the formation of biologically active proteins. We have studied the effects of such mutations at 13 different sites on the properties of the multifunctional tail spike protein of bacteriophage P22, a thermostable structural protein composed of 76,000 M_r chains.Using multiple mutant strains blocked in capsid assembly, we have examined the free mutant tail spikes that accumulate in active form at permissive temperature. When assayed for the ability to bind to phage heads at the restrictive temperature, the mutant proteins were as active as the wild type. Similarly, when assayed for the ability to adsorb to bacteria at restrictive temperature, the mutant proteins were as active as the wild type. Thus the temperature-sensitive phenotypes of the mutants are not due to the thermolability of these functions in the mature mutant protein.The wild-type protein is heat-resistant, requiring incubation at 90 °C, to give a half-time of inactivation of ten minutes. The 13 ts mutant proteins, once matured at 30 °C, were as resistant as the wild-type protein to inactivation at elevated temperatures.Though the mature wild-type protein is heat stable, its maturation is heat-sensitive; the number of polypeptide chains synthesized at 30 °C and 39 °C is the same, but the yield of active tail spikes at 39 °C is only 25% of the yield at 30 °C.The results show that the amino acid substitutions in the mutant proteins, though lethal for the formation of the virus at 39 °C, do not affect the thermostability of the mature tail spike protein formed at 30 °C. They may act by destabilizing thermolabile intermediates in the folding or subunit assembly of the tail spike protein.     

Studies on temperature-dependent ultraviolet light-sensitive mutants of bacteriophage T4: the structural gene for T4 endonuclease V.

Mutants of bacteriophage T4 which exhibit increased sensitivity to ultraviolet radiation specifically at high temperature were isolated after mutagenesis with hydroxylamine. At 42 °C the mutants are twice as sensitive to ultraviolet light as T4D, whereas at 30 °C they exhibit survival curves almost identical to that of the wild-type strain. Complementation tests revealed that the mutants possess temperature-sensitive mutations in the v gene.Evidence is presented to show that T4 endonuclease V produced by the mutants is more thermolabile than the enzyme of the wild-type. (1) Extracts of cells infected with the mutants were capable of excising pyrimidine dimers from ultraviolet irradiated T4 DNA at 30 °C, but no selective release of dimers was induced at 42 °C. (2) Endonuclease V produced by the mutant was inactivated more rapidly than was the enzyme from T4D-infected cells when the purified enzymes were incubated in a buffer at 42 °C. From these results it is evident that the v gene is the structural gene for T4 endonuclease V, which plays an essential role in the excision-repair of ultraviolet light-damaged DNA.The time of action of the repair endonuclease was determined by using the mutant. Survival of a temperature-sensitive v mutant, exposed to ultraviolet light, increased when infected cells were incubated at 30 °C for at least ten minutes and then transferred to 42 °C. It appears that repair of DNA proceeds during an early stage of phage development.     

Mechanism of vesicular stomatitis virus mRNA decay

The chemical and functional stability of the five vesicular stomatitis virus (VSV) messenger RNAs during infection of Chinese hamster ovary (CHO) cells was studied using the temperature-sensitive mutant, tsG114. By incubating infected cells at the nonpermissive temperature (39 °C), RNA synthesis was blocked and the five VSV mRNAs decayed chemically and functionally with a half-life of 1 to 1.5 h. However, all five VSV mRNAs were stable in vivo at 39 °C when protein synthesis was blocked with either cycloheximide or emetine. In contrast, when pactamycin was used to inhibit protein synthesis, the chemical and functional decay rates of the VSV mRNAs were indistinguishable from those observed in the absence of antibiotic. On the basis of the mode of action of each of the antibiotic inhibitors, these data imply that (a) ribosome movement along VSV mRNAs plays no role in their stabilities, and (b) each VSV mRNA contains a nuclease-sensitive site, at its 5′ end at or near the initiation site, which regulates its decay in vivo.     

Identification of 23 complementation groups required for post-translational events in the yeast secretory pathway

Cells of a Saccharomyces cerevisiae mutant that is temperature-sensitive for secretion and cell surface growth become dense during incubation at the non-permissive temperature (37°C). This property allows the selection of additional secretory mutants by sedimentation of mutagenized cells on a Ludox density gradient. Colonies derived from dense cells are screened for conditional growth and secretion of invertase and acid phosphatase. The sec mutant strains that accumulate an abnormally large intracellular pool of invertase at 37°C (188 mutant clones) fall into 23 complementation groups, and the distribution of mutant alleles suggests that more complementation groups could be found. Bud emergence and incorporation of a plasma membrane sulfate permease activity stop quickly after a shift to 37°C. Many of the mutants are thermoreversible; upon return to the permissive temperature (25°C) the accumulated invertase is secreted. Electron microscopy of sec mutant cells reveals, with one exception, the temperature-dependent accumulation of membrane-enclosed secretory organelles. We suggest that these structures represent intermediates in a pathway in which secretion and plasma membrane assembly are colinear.     

A novel temperature-sensitive mammalian cell line exhibiting defective prophase progression

A temperature-sensitive mammalian cell line has been isolated which grows and divides normally at the permissive temperature of 33°C. When incubated at 39°C, the nonpermissive temperature, interphase cells continue to enter a prophase-like state. Chromatin-like material condenses and coalesces into dark-staining clumps rather than into discernible chromosomes. Disappearance of the nuclear boundary is observed, but re-formation of the boundary around the clumps fails to occur. Incorporation of labeled precursors reveals a decrease in protein synthesis which is accompanied by a slower decrease in DNA synthesis. Approximately 0.2% of the mutant cells revert in their capability of growth and cell division at 39°C. These “revertants” are found to contain a higher number of chromosomes. The isolation of this mutant is based on the initial observation that the cells become rounded at the nonpermissive temperature. The cell-rounding process characteristic of mitotic cells should serve as a useful marker in the isolation of mitotic mutants.     

Alterations in the production of hemocytes due to a neoplastic mutation of Drosophila melanogaster

The hemocytes of a genetically induced, temperature-sensitive lethal mutation of Drosophila, Tum¹, were examined both quantitatively and qualitatively during the third larval instar. At the tumor-permissive temperature, 29°C, there was a fourfold increase in the concentration of circulating hemocytes in mutant larvae as compared to control. Additionally, the relative frequency of lamellocytes was 30 times greater in Tum¹ larvae than Basc in the early third instar. However, the severity of this abnormality gradually diminished as Tum¹ approached pupariation; though high frequencies of lamellocytes were always present. At the tumor-restrictive temperature (15°C) the concentration of circulating hemocytes was over twice that found at 29°C for Tum¹ larvae, and did not change during the course of third instar. However, in contrast to 29°C there was no abnormal increase in the frequency of lamellocytes at the tumor-restrictive temperature. Control larvae had equivalent concentrations of hemocytes at both temperatures. In one of two temperature shift experiments, Tum¹ larvae shifted from 15° to 29°C at the beginning of third instar expressed the abnormal hemocyte concentration and differentiation associated with larvae raised continuously at 29°C. In addition, Tum¹ larvae shifted from 29° to 15°C expressed reduced abnormalities of hemocyte differentiation, e.g., with fewer lamellocytes in circulation. The possibility of a temperature-sensitive period for the activation of the Tum¹ gene is discussed.     

Temperature-sensitive mutants blocked in the folding or subunit assembly of the bacteriophage P22 tail spike protein: III. Inactive polypeptide chains synthesized at 39 °C

Salmonella typhimurium cells infected by temperature-sensitive mutants in gene 9 of bacteriophage P22 at the restrictive temperature (39 °C) fail to accumulate functional tail spike protein. We report here studies of the inactive mutant tail spike polypeptide chains synthesized at 39 °C by temperature-sensitive mutants at 15 different sites of gene 9. For all 15 mutants, the gene 9 polypeptide chains were synthesized at 39 °C at rates similar to wild type. The mutant polypeptide chains were stable within the infected cells.The inactive polypeptide chains were tested for three functions displayed by the mature tail spike protein: irreversible binding to phage heads, endorhamnosidase activity, and reaction with anti-tail antibody. The 15 mutant proteins that accumulated at 39 °C lacked all three functions. Since the amino acid substitutions do not affect these functions of the mature protein, the mutant polypeptide chains synthesized at 39 °C have a conformation very different from the wild type, and different from the same proteins when matured at 30 °C. The fact that amino acid substitutions throughout the 76,000 M_r polypeptide chain prevent all three functions suggests that the mutations prevent the correct folding of the gene 9 polypeptide chain at restrictive temperature. Thus, these mutations identify sites in the polypeptide chain critical for protein maturation.Many of the mutant proteins could be activated in the absence of new protein synthesis by shifting infected cells from restrictive to permissive temperature before cell lysis. For these mutants, the immature chains accumulating at high temperature must be reversibly related to intermediates in protein folding or subunit assembly.     

Regulation of Synthesis of Chlorophyll, Carotene, Ribulosel,5-diP Carboxylase and Phosphoribulokinase in a Temperature-sensitive Chlorophyll Mutant of Medicago sativa

The activities of several enzymes were studied in a temperature-sensitive chlorophyll mutant of alfalfa (Medicago saliva). In leaves grown at 10°C photosynthetic capacity was essentially nil with ribulose-1,5-diP carboxylase, chlorophyll, and carolene present in greatly limiting concentrations. The activity of phosphoribulokinase was 3.5 times lower at 10°C than at 27°C, but was still sufficiently high at 10°C to not limit the rate of CO₂ fixation. Activities of phosphoriboisomerase, phosphoenolpyruvate carboxylase, glucose-6-P dehydrogenase and malate dehydrogenase were not different at 10°C and 27°C. The low fraction I protein content (which also accounts for the ribulose-1,5-dip carboxylase activity in alfalfa) indicated that synthesis of the carboxylase was effectively blocked at 10°C. A large, comparable increase in carboxylase activity and in concentration of fraction I protein in alfalfa leaves grown at 27°C indicated that the carboxylase was synthesized de novo. The initial induction of the carboxylase, chlorophyll, and carotene may be related, but after induction the carboxylase was not linearly correlated with the other two and had a different temperature optima. Nevertheless, the synthesis of each appeared to be regulated by the temperature-sensitive gene of this mutant.     

Time of replication of genes responsible for a temperature-sensitive function in a cell cycle-specific ts mutant from a hamster cell line

A method involving short pulses of 5-bromodeoxyuridine (brUdRib) followed by irraidation with 313 nm light was used to locate the time of replication of certain genes during the cell cycle of two cell lines, AF8 and AL106. AF8, a temperature-sensitive mutant of BHK21/13 cells, grows at 33°C but not at 39.5°C. AL106, a hybrid clone of tsAF8 and SV-40 transformed Lesch-Nyhan fibroblasts (LNSV), which retains all hamster chromosomes and one human chromosome (No. 3), has the ability to grow at 39.5°C. AF8 and AL106 cells synchronized at the G₁-S boundary were released from their block and pulsed with brUdRib for 2-hour periods during the S phase. The cells were subsequently irradiated with 313 nm light. Colony-forming efficiency and revertants frequency were studied. Incorporation of brUdRib during the early S phase (0–4 hours from the begining of S), decreased the colony-forming efficiency of AL106 cells both at 33°C and 39.5°C, and also of AF8 cells at 33°C. No AF8 colonies grew at the nonpermissive temperature regardless of the treatment. Thus the time of replication of genes responsible for colony-forming ability was the same in tsAF8 at the permissive temperature and in AL106 at both temperatures. The time of replication of the genes responsible for the ts function in AF8 cells was located by determining the revertants frequency in synchronized AF8 cells pulsed with brUdRib and irradiated during 1- to 2-hour periods of the S phase. Back-mutants were scored by counting the number of clones capable of growing at 39.5°C (nonpermissive for AF8 cells). The highest frequency of induced back-mutations occurred in synchronized AF8 cells pulsed with brUdRib (and irradiated) between two to four hours from the begining of the S phase. Exposure to brUdRib during other periods of the S phase or during G₁ had no effect on the reversion rate. This method can be used to locate the time of replication (in S) of ts genes in other temperature-sensitive mutants or of other specific genes in other conditional mutants.     

Yeast tRNA ligase mutants are nonviable and accumulate tRNA splicing intermediates.

We show here that yeast tRNA ligase protein is essential in the cell and participates in joining together tRNA half-molecules resulting from excision of the intron by the splicing endonuclease. A haploid yeast strain carrying a chromosomal deletion of the ligase gene is viable only if ligase protein can be supplied from a plasmid copy of the gene. When synthesis of the plasmid-borne ligase gene is repressed, cells eventually die and accumulate endonuclease cut but unligated half-molecules and intervening sequences. Half-molecules that accumulate appear to be fully end-processed. Two temperature-sensitive ligase mutant strains have been isolated; these strains accumulate a similar set of unligated half-molecules at the nonpermissive temperature.     

Roles of protein synthesis and tRNA aminoacylation in the regulation of intracellular protein breakdown in E. coli

The previously suggested roles of protein synthesis and tRNA aminoacylation in the regulation of intracellular protein breakdown were examined in strains of E. coli temperature-sensitive for aminoacyl-tRNA synthetases. Direct measurements of tRNA aminoacylation show no correlation between the degree of tRNA charging and the rate of protein breakdown. Protein breakdown was accelerated by transfer from 30°C to 42°C to about the same degree in temperature-sensitive mutants as in related normal strains. Deprivation of inorganic phosphate at the high temperature stimulated further protein breakdown in normal, but not in temperature-sensitive strains. It is concluded that the regulation of protein breakdown requires concomitant protein synthesis and is not influenced by the level of aminoacylation of tRNA.     

Disappearance of a basic chromosomal protein from cells of a mouse temperature-sensitive mutant defective in histone phosphorylation

The amount of a basic nuclear protein which migrates a little slower than histone H1 in urea-acetic acid-polyacrylamide gel electrophoresis and a little faster than H1 in sodium dodecylsulfate-polyacrylamide gel electrophoresis, decreases when cells of a temperature-sensitive mutant, ts85, derived from a mouse carcinoma cell line, are incubated at the nonpermissive temperature (39°C). This protein appears again, when cells cultured at 39°C are shifted down to the permissive temperature, indifferent to the added cycloheximide. Neither in wild type nor in a revertant of ts85, the protein disappeared at 39°C. Since the ts85 cells were found to be defective in chromosome condensation and in the phosphorylation of histone H1 at 39°C (1,2), this basic protein may relate to the both events.     

Glutamic Acid Production in Biotin-rich Media by Temperature-sensitive Mutants of Brevibacterium lactofermentum,a Novel Fermentation Process

Temperature-sensitive mutants were derived from Brevibacterium lactofermentum strain 2256 in a search for mutants which would produce a large amount of L-glutamic acid in biotin- rich media at the nonpermissive temperature. A total of 159 mutant strains was selected which showed adequate growth at 30°C but showed little or no growth at 37°C on minimal medium. Twenty of these were found to produce glutamic acid in a biotin-rich medium after a temperature shift from 30°C to 37°C, while the wild-type strain 2256 did not produce it under the same cultural condition.

One of the typical mutant strains, Ts-88, produced approximately 2g/dl of glutamic acid from beet molasses (the yield > 55%) in the presence of 33 µg/liter of biotin when tempera- , ture was shifted from 30°C to 40°C during the cultivation. It was concluded that, by controlling only temperature during fermentation, glutamic acid production could be realized in media containing biotin-rich natural carbon sources, without any chemical control such as the addition of expensive surface-active agents or antibiotics. Characteristics and merits of the novel fermentation process are discussed.     

Synthesis of complex forms of bacteriophage phiX174 double-stranded DNA in a temperature-sensitive dnaC mutant of Escherichia coli C.

Fast-sedimenting forms of bacteriophage phiX174 double-stranded replicative-form DNA observed in normal infections continued to accumulate at the nonpermissive temperature in a temperature-sensitive dnaC mutant of Escherichia coli. These complex molecules accounted for up to half of the DNA synthesized during short pulses at the nonpermissive temperature. They were the dead-end products of DNA synthesis, not intermediates in normal replicative-form replication. The data suggest that these higher-than-normal-molecular-weight DNA molecules result from abnormal initiation of phiX174 replicative-form DNA replication.