Consequences of herpes simplex virus type 2 and human cell interaction at supraoptimal temperatures.

The consequences of herpes simplex virus type 2 (HSV-2) and human embryonic fibroblast cell interaction at different temperatures (37, 40, and 42 degrees C) were investigated. Incubation at 37 or 40 degrees C was permissive for HSV-2 inhibition of host DNA synthesis, induction of virus-specific DNA replication, and infectious virus production. The amount of [methyl-3H]thymidine incorporated into viral DNA and the final yield of new infectious virus were significantly reduced at 40 degrees C compared to 37 degrees C. At 42 degrees C, detectable virus-specific DNA synthesis was totally blocked. Maximum stimulation of host cell DNA synthesis at 42 degrees C was measured after a multiplicity of infection of 0.5 to 1.0 PFU/cell. By autoradiography, data indicated that HSV-2 stimulates host cell chromosomal DNA synthesis. Stimulation of thymidine kinase activity with thermostability properties in common with a virus enzyme was detected during the first 24 h of infection at 42 degrees C, after 24 h the enhanced thymidine kinase activity had properties in common with host cell isozymes. The data obtained during this investigation indicated that stimulation of host cell DNA synthesis does not require viral DNA synthesis.     

A DNA polymerase from a thermoacidophilic archaebacterium: evolutionary and technological interests

The archaebacteria constitute a group of prokaryotes with an intermediate phylogenetic position between eukaryotes and eubacteria. The study of their DNA polymerases may provide valuable information about putative evolutionary relationships between prokaryotic and eukaryotic DNA polymerases. As a first step towards this goal, we have purified to near homogeneity a DNA polymerase from the thermoacidophilic archaebacterium Sulfolobus acidocaldarius. This enzyme is a monomeric protein of 100 kDa which can catalyze DNA synthesis using either activated calf thymus DNA or oligonucleotide-primed single-stranded DNA as a template. The activity is optimal at 70 degrees C and the enzyme is thermostable up to 80 degrees C; however, it can still polymerize up to 200 nucleotides at 100 degrees C. These remarkable thermophilic properties and thermostability permit examination of the mechanism of DNA synthesis under conditions of decreased stability of the DNA helix. Furthermore, these properties make S. acidocaldarius DNA polymerase a very efficient enzyme to be used in DNA amplification by the recently developed polymerase chain reaction method (PCR) as well as in the Sanger DNA sequencing technique.     

Physiological Effects of Growth of an Escherichia coli Temperature-Sensitive dnaZ Mutant at Nonpermissive Temperatures

The physiological effects of incubation at nonpermissive temperatures of Escherichia coli mutants that carry a temperature-sensitive dnaZ allele [dnaZ(Ts)2016] were examined. The temperature at which the dnaZ(Ts) protein becomes inactivated in vivo was investigated by measurements of deoxyribonucleic acid (DNA) synthesis at temperatures intermediate between permissive and nonpermissive. DNA synthesis inhibition was reversible by reducing the temperature of cultures from 42 to 30 degrees C; DNA synthesis resumed immediately after temperature reduction and occurred even in the presence of chloramphenicol. Inasmuch as DNA synthesis could be resumed in the absence of protein synthesis, we concluded that the protein product of the dnaZ allele (Ts)2016 is renaturable. Cell division, also inhibited by 42 degrees C incubation, resumed after temperature reduction, but the length of time required for resumption depended on the duration of the period at 42 degrees C. Replicative synthesis of cellular DNA, examined in vitro in toluene-permeabilized cells, was temperature sensitive. Excision repair of ultraviolet light-induced DNA lesions was partially inhibited in dnaZ(Ts) cells at 42 degrees C. The dnaZ(+) product participated in the synthesis of both Okazaki piece (8-12S) and high-molecular-weight DNA. During incubation of dnaZ(Ts)(lambda) lysogens at 42 degrees C, prophage induction occurred, and progeny phage were produced during subsequent incubation at 30 degrees C. The temperature sensitivity of both DNA synthesis and cell division in the dnaZ(Ts)2016 mutant was suppressed by high concentrations of sucrose, lactose, or NaCl. Incubation at 42 degrees C was neither mutagenic nor antimutagenic for the dnaZ(Ts) mutant.     

Characterization of RNA synthesis in an Escherichia coli mutant with a temperature-sensitive lesion in stable RNA synthesis

Previous experiments with Escherichia coli strain 2S142 have shown that the synthesis of stable RNA is preferentially blocked at the restrictive temperature. In this paper, we have examined the capacity of this mutant strain to synthesize RNA in vitro. Growth of the strain for as short a period as 10 min at 42 degrees C resulted in a 40 to 60% loss of RNA synthetic capacity and a fourfold decrease in percent rRNA synthesized in toluenized cell preparations. The time course for the loss and recovery of this RNA synthetic capacity correlated very well with the changes in RNA synthesis observed in vivo. We found no difference in temperature sensitivity of the purified RNA polymerase from the mutant and the parental strains. Moreover, there was no detectable alteration in the amount of enzyme, specific activity of the enzyme, or electrophoretic mobility of the subunits when the mutant strain was grown at 42 degrees C. The capacity for rRNA synthesis was also measured with the Zubay in vitro system (Reiness et al., Proc. Natl. Acad. Sci. 72:2881-2885, 1975). Supernatant fractions (S-30) prepared from cells grown at 30 degrees C were capable of up to 31.2% rRNA synthesis, using phi 80d3 DNA as template. S-30 fractions from cells grown at 42 degrees C synthesized 8.6% rRNA. The bottom one-third of the S-100 fraction and the ribosomal salt wash from 30 degrees C cells contained one or more factors which partially restored preferential rRNA synthesis in S-30 fractions from cells grown at 42 degrees C. Preliminary evidence suggests that the factor(s) is protein in nature.     

Molecular basis for the maximum growth temperature of an obligately psychrophilic yeast, Leucosporidium stokesii.

Cells of the obligately psychrophilic yeast Leucosporidium stokesii were subjected to permissive (15 and 20 degrees C) and restrictive (23 and 25 degrees C) temperatures to determine the event(s) responsible for the low maximum growth temperature of this organism. An investigation of subcellular morphology by nuclear staining revealed that buds formed at 20 degrees C were anucleate but showed nuclear migration within the parent cell. Cells incubated initially at 23 degrees C and then shifted down to a permissive growth temperature of 15 degrees C in the presence of a deoxyribonucleic acid (DNA) synthesis inhibitor, hydroxyurea, confirmed the observation that the anucleate condition of atypical buds was the result of temperature-sensitive DNA synthesis. Concomitantly, the incorporation of labeled adenine into DNA was inhibited at 23 and 25 degrees C. The synthesis of ribonucleic acid, however, was enhanced at 23 degrees C but impaired at 25 degres C. Similarly, protein synthesis was unaffected at either restrictive temperature.     

Low-temperature conditional cell division mutants of Escherichia coli.

Fifteen low-temperature conditional division mutants of Escherichia coli K-12 was isolated. They grew normally at 39 degrees C but formed filaments at 30 degrees C. All exhibited a coordinated burst of cell division when the filaments were shifted to the permissive temperature (39 degrees C). None of the various agents that stimulate cell division in other mutant systems (salt, sucrose, ethanol, and chloramphenicol) was very effective in restoring colony-forming ability at 25 degrees C or in stimulating cell division in broth. One of these mutants, strain JS10, was found to have an altered cell envelope as evidenced by increased sensitivity to deoxycholate and antibiotics, as well as leakage of ribonulcease I, a periplasmic enzyme. This mutant had normal rates of DNA synthesis, RNA synthesis, and phospholipid synthesis at both the nonpermissive and permissive temperatures. However, strain JS10 required new protein synthesis in the apparent absence of new RNA synthesis for division of filaments at the permissive temperature. The division of lesion in strain JS10 is cotransducible with malA, aroB, and glpD and maps within min 72 to 75 on the E. coli chromosome.     

A Mutation in the gene-encoding bacteriophage T7 DNA polymerase that renders the phage temperature-sensitive

Gene 5 of bacteriophage T7 encodes a DNA polymerase essential for phage replication. A single point mutation in gene 5 confers temperature sensitivity for phage growth. The mutation results in an alanine to valine substitution at residue 73 in the exonuclease domain. Upon infection of Escherichia coli by the temperature-sensitive phage at 42 degrees C, there is no detectable T7 DNA synthesis in vivo. DNA polymerase activity in these phage-infected cell extracts is undetectable at assay temperatures of 30 degrees C or 42 degrees C. Upon infection at 30 degrees C, both DNA synthesis in vivo and DNA polymerase activity in cell extracts assayed at 30 degrees C or 42 degrees C approach levels observed using wild-type T7 phage. The amount of soluble gene 5 protein produced at 42 degrees C is comparable to that produced at 30 degrees C, indicating that the temperature-sensitive phenotype is not due to reduced expression, stability, or solubility. Thus the polymerase induced at elevated temperatures by the temperature-sensitive phage is functionally inactive. Consistent with this observation, biochemical properties and heat inactivation profiles of the genetically altered enzyme over-produced at 30 degrees C closely resemble that of wild-type T7 DNA polymerase. It is likely that the polymerase produced at elevated temperatures is a misfolded intermediate in its folding pathway.     

Morphogenesis of bacteriophage phi 29 of Bacillus subtilis: DNA-gp3 intermediate in in vivo and in vitro assembly

The assembly of phage phi 29 occurs by a single pathway, and DNA-protein (DNA-gp3) has been shown to be an intermediate on the assembly pathway by a highly efficient in vitro complementation. At 30 degrees C, about one-half of the viral DNA synthesized was assembled into mature phage, and the absolute plating efficiency of phi 29 approached unity. DNA packaging at 45 degrees C was comparable to that at 30 degrees C, but the burst size was reduced by one-third. When cells infected with mutant ts3(132) at 30 degrees C to permit DNA synthesis were shifted to 45 degrees C before phage assembly, DNA synthesis ceased and no phage were produced. However, a variable amount of DNA packaging occurred. Superinfection by wild-type phage reinitiated ts3(132) DNA synthesis at 45 degrees C, and if native gp3 was covalently linked to this DNA during superinfection replication, it was effectively packaged and assembled. Treatment of the DNA-gp3 complex with trypsin prevented in vitro maturation of phi 29, although substantial DNA packaging occurred. A functional gp3 linked to the 5' termini of phi 29 DNA is a requirement for effective phage assembly in vivo and in vitro.     

Synthesis of bacteriophage phiC DNA in dna mutants of Esherichia coli.

Host dna functions involved in the replication of microvirid phage phiC DNA were investigated in vivo. Although growth of this phage was markedly inhibited even at 35-37 degrees C even in dna+ host, conversion of the infecting single-stranded DNA into the double-stranded parental replicative form (stage I synthesis) occurred normally at 43 degrees C in dna+, dnaA, dnaB, dnaC(D), and dnaE cells. In dnaG mutant, the stage I synthesis was severely inhibited at 43 degrees C but not at 30 degrees C. The stage I replication of phiC DNA was clearly thermosensitive in dnaZ cells incubated in nutrient broth. In Tris-casamino acids-glucose medium, however, the dnaZ mutant sufficiently supported synthesis of the parental replicative form. At 43 degrees C, synthesis of the progeny replicative form DNA (stage II replication) was significantly inhibited even in dna+ cells and was nearly completely blocked in dnaB or dnaC(D) mutant. At 37 degrees C, the stage II replication proceeded normally in dna+ bacteria.     

Identification of temperature-sensitive DNA- mutants of Chinese hamster cells affected in cellular and viral DNA synthesis.

We described a strategy which facilitates the identification of cell mutants which are restricted in DNA synthesis in a temperature-dependent manner. A collection of over 200 cell mutants temperature-sensitive for growth was isolated in established Chinese hamster cell lines (CHO and V79) by a variety of selective and nonselective techniques. Approximately 10% of these mutants were identified as ts DNA- based on differential inhibition of macromolecular synthesis at the restrictive temperature (39 degrees C) as assessed by incorporation of [3H]thymidine and [35S]methionine. Nine such mutants, selected for further study, demonstrated rapid shutoff of DNA replication at 39 degrees C. Infections with two classes of DNA viruses extensively dependent on host-cell functions for their replication were used to distinguish defects in DNA synthesis itself from those predominantly affecting other aspects of DNA replication. All cell mutants supported human adenovirus type 2 (Ad2) and mouse polyomavirus DNA synthesis at the permissive temperature. Five of the nine mutants (JB3-B, JB3-O, JB7-K, JB8-D, and JB11-J) restricted polyomavirus DNA replication upon transfection with viral sequences at 33 degrees C and subsequent shift to 39 degrees C either before or after the onset of viral DNA synthesis. Only one of these mutants (JB3-B) also restricted Ad2 DNA synthesis after virion infection under comparable conditions. No mutant was both restrictive for Ad2 and permissive for polyomavirus DNA synthesis at 39 degrees C. The differential effect of these cell mutants on viral DNA synthesis is expected to assist subsequent definition of the biochemical defect responsible.     

Enhancement of thermal killing by polyamines. IV. Effects of heat and spermine on protein synthesis and ornithine decarboxylase activity.

Protein synthesis is shown to be very heat-sensitive in Chinese hamster cells. It is shut off completely following 15-20 min at 42 degrees C whereas RNA and DNA syntheses are affected only after much longer exposure times. Cells recover from inhibition of protein synthesis upon transfer to 37 degrees C. The degree of recovery is inversely related to the duration of heat exposure and it fits cell survival quantitatively. Cells which become temporarily heat-resistant by prior heat-treatment, are able to recover translational capacity even after a very long exposure to heat (4 h at 42 degrees C). Spermine, which enhances heat-induced cell killing, does not increase the response to heat of protein, RNA and DNA synthesis. Ornithine decarboxylase (ODC, EC 4.1.1.17) activity is lost exponentially following a 20 min lag period during exposure at 42 degrees C. The half-life observed (12 min) is in agreement with the reported values of half-life of decay of ODC in other systems. It is concluded that the loss of activity is due to the shut-off of translation. The activity of ODC is recovered upon transfer to 37 degrees C. The presence of spermine during heating does not affect the loss of enzyme activity but delays its recovery by about 3 h upon transfer to 37 degrees C.     

The Characteristics and Genetic Map Location of a Temperature Sensitive DNA Mutant of E. COLI K12

A temperature sensitive strain of E. coli K12 has been isolated in which residual DNA synthesis occurs at the 40 degrees C restrictive temperature; syntheses of RNA, protein and DNA precursors are not directly affected. The mutation has been designated dna-325 and is located at 89 min on the E. coli map in the same region where the dnaC locus is found. dnaC mutants are considered to be defective in DNA initiation. Some of the data are consistent with the view that the dna-325 mutation is temperature sensitive in the process of DNA initiation rather than DNA chain elongation: (1) more than two cell divisions occur after a shift to 40 degrees C; (2) upon a shift down to 30 degrees C, cell division occurs again only after the DNA content of the cells has doubled; (3) 80% more DNA is made at 30 degrees C in the presence of chloramphenicol after prior inhibition of DNA synthesis at 40 degrees C. These three observations indicate that rounds of DNA replication were completed at 40 degrees C. Also (4) infective lambda particles can be made at 40 degrees C long after bacterial DNA replication has ceased. It appears however that some DNA initiation can occur at 40 degrees C since (1) a limited amount of DNA synthesis does occur at 40 degrees C after prior alignment of the chromosomes by amino acid starvation at 30 degrees C, and (2) after incubation in bromouracil at the restrictive temperature, heavy DNA is found with both strands containing bromouracil.     

Comparative stability and catalytic and chemical properties of the sulfate-activating enzymes from Penicillium chrysogenum (mesophile) and Penicillium duponti (thermophile).

ATP sulfurylases from Penicillium chrysogenum (a mesophile) and from Penicillium duponti (a thermophile) had a native molecular weight of about 440,000 and a subunit molecular weight of about 69,000. (The P. duponti subunit appeared to be a little smaller than the P. chrysogenum subunit.) The P. duponti enzyme was about 100 times more heat stable than the P. chrysogenum enzyme; k inact (the first-order rate constant for inactivation) at 65 degrees C = 3.3 X 10(-4) s-1 for P. duponti and 3.0 X 10(-2) s-1 for P. chrysogenum. The P. duponti enzyme was also more stable to low pH and urea at 30 degrees C. Rabbit serum antibodies to each enzyme showed heterologous cross-reaction. Amino acid analyses disclosed no major compositional differences between the two enzymes. The analogous Km and Ki values of the forward and reverse reactions were also essentially identical at 30 degrees C. At 30 degrees C, the physiologically important adenosine 5'-phosphosulfate (APS) synthesis activity of the P. duponti enzyme was 4 U mg of protein-1, which is about half that of the P. chrysogenum enzyme. The molybdolysis and ATP synthesis activities of the P. duponti enzyme at 30 degrees C were similar to those of the P. chrysogenum enzyme. At 50 degrees C, the APS synthesis activity of the P. duponti enzyme was 12 to 19 U mg of protein-1, which was higher than that of the P. chrysogenum enzyme at 30 degrees C (8 +/- 1 U mg of protein-1). Treatment of the P. chrysogenum enzyme with 5,5'-dithiobis(2-nitrobenzoate) (DTNB) at 30 degrees C under nondenaturing conditions modified one free sulfhydryl group per subunit. Vmax was not significantly altered, but the catalytic activity at low magnesium-ATP or SO4(2-) (or MoO4(2-)) was markedly reduced. Chemical modification with tetranitromethane had the same results on the kinetics. The native P. duponti enzyme was relatively unreactive toward DTNB or tetranitromethane at 30 degrees C and pH 8.0 or pH 9.0, but at 50 degrees C and pH 8.0, DTNB rapidly modified one SH group per subunit. APS kinase (the second sulfate-activating enzyme) of P. chrysogenum dissociated into inactive subunits at 42 degrees C. The P. duponti enzyme remained intact and active at 42 degrees C.     

Purification and characterization of an extremely thermostable cyclomaltodextrin glucanotransferase from a newly isolated hyperthermophilic archaeon, a Thermococcus sp

The extremely thermophilic anaerobic archaeon strain B1001 was isolated from a hot-spring environment in Japan. The cells were irregular cocci, 0.5 to 1.0 micrometers in diameter. The new isolate grew at temperatures between 60 and 95 degrees C (optimum, 85 degrees C), from pH 5.0 to 9.0 (optimum, pH 7.0), and from 1.0 to 6.0% NaCl (optimum, 2.0%). The G+C content of the genomic DNA was 43.0 mol%. The 16S rRNA gene sequencing of strain B1001 indicated that it belongs to the genus Thermococcus. During growth on starch, the strain produced a thermostable cyclomaltodextrin glucanotransferase (CGTase). The enzyme was purified 1,750-fold, and the molecular mass was determined to be 83 kDa by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. Incubation at 120 degrees C with SDS and 2-mercaptoethanol was required for complete unfolding. The optimum temperatures for starch-degrading activity and cyclodextrin synthesis activity were 110 and 90 to 100 degrees C, respectively. The optimum pH for enzyme activity was pH 5.0 to 5.5. At pH 5.0, the half-life of the enzyme was 40 min at 110 degrees C. The enzyme formed mainly alpha-cyclodextrin with small amounts of beta- and gamma-cyclodextrins from starch. This is the first report on the presence of the extremely thermostable CGTase from hyperthermophilic archaea.     

A nuclear mutant of Saccharomyces cerevisiae deficient in mitochondrial DNA replication and polymerase activity

We have isolated a thermosensitive mutant which is transformed into a population of cells devoid of mitochondrial DNA (rho 0 cells) at 35 degrees C and is deficient in mitochondrial (mt) DNA polymerase activity. A single recessive nuclear mutation (mip1) is responsible for rho 0 phenotype and mtDNA polymerase deficiency in vitro. At 25 degrees C (or 30 degrees C) a dominant suppressor mutation (SUP) masks the deficiency in vivo. The meiotic segregants (mip1 sup) which do not harbor the suppressor have a rho 0 phenotype both at 25 and 35 degrees C. They have no mtDNA polymerase activity, in contrast with MIP rho 0 mutants of mitochondrial inheritance which do exhibit mtDNA polymerase activity. In the thermosensitive mutant (mip1 SUP), the replication of mtDNA observed in vivo at 30 degrees C is completely abolished at 35 degrees C. In the meiotic segregants (mip1 sup), no mtDNA replication takes place at 30 and 35 degrees C. The synthesis of nuclear DNA is not affected. DNA polymerases may have replicative and/or repair activity. There is no evidence that mip mutants are deficient in mtDNA repair. In contrast the MIP gene product is strictly required for the replication of mtDNA and for the expression of the mtDNA polymerase activity. This enzyme might be the replicase of mtDNA.     

Poly(ADP-ribose) polymerase activity in mouse cells which exhibit temperature-sensitive DNA synthesis

The poly(ADP-ribose) polymerase activity of wild-type mouse L cells and of Balb/C-3T3 mouse fibroblasts remained relatively unchanged (at approx. 400 nmol substrate utilized/mg DNA per h) in actively-growing cells incubated at 34 degrees C or at 38.5 degrees C for at least 72 h. A similar result was obtained with the following temperature-sensitive cells grown at the permissive temperature (34 degrees C): ts A1S9 mouse L cells, ts C1 mouse L cells and Balb/C-3T3 ts mouse fibroblasts. The poly(ADP-ribose) polymerase activity of the temperature-sensitive cells was little affected during incubation for 20-24 h at the non-permissive temperature of 38.5 degrees C under which conditions temperature-inactivation of DNA replication was complete. Thereafter, this enzyme activity was found to increase some 2-fold, at a time when normal semi-conservative DNA synthesis was totally suppressed and replaced by repair replication (Sheinin, R. and Guttman, S. (1977) Biochim. Biophys. Acta 479, 105-118; Sheinin, R., Dardick, I. and Doane, F.W. (1980) Exp. Cell. Res., in the press).     

Characterization of a temperature-sensitive DNA replication mutant of Staphylococcus aureus

A temperature-sensitive DNA replication mutant of Staphylococcus aureus NCTC 8325 has been isolated and characterized. After transfer to the non-permissive-temperature (42 degrees C), DNA synthesis continued for 30 min and the mean DNA content increased by 56%. The amount of residual DNA synthesis was not reduced when the non-permissive temperature was raised, nor when chloramphenicol was added at the time of the temperature shift. During incubation at 42 degrees C, mutant bacteria accumulated the capacity to synthesize DNA after return to the permissive temperature (30 degrees C) in the presence of chloramphenicol. This capacity was lost when chloramphenicol was present at 42 degrees C. The properties of the mutant are consistent with a defect in the initiation of DNA replication at 42 degrees C.     

Effect of temperature shifts on extracellular proteinase-specific mRNA pools in Pseudomonas fluorescens B52.

The influence of a shift in temperature from 20 to 32 degrees C on extracellular proteinase synthesis by Pseudomonas fluorescens B52 was examined. When cells actively synthesizing proteinase at 20 degrees C were shifted to 32 degrees C, enzyme synthesis ceased immediately. After 30 min at 32 degrees C, cells recovered at 20 degrees C after a lag of 30 min. Rifampin and chloramphenicol prevented recovery of synthesis at 20 degrees C. Rifampin-insensitive proteinase synthesis (an indirect measure of proteinase-specific mRNA pools) decreased after the exposure of cells to 32 degrees C for 30 min but was recovered during incubation at 20 degrees C. Controls not exposed to a temperature shift experienced no loss of rifampin-independent synthesis. Cells experienced a 50% reduction in mRNA pools after 15 min at 32 degrees C. The data support the working hypothesis that the loss of mRNA pools after treatment at 32 degrees C is responsible for the lag before the recovery of extracellular proteinase synthesis.     

Relationship of critical temperature to macromolecular synthesis and growth yield in Psychrobacter cryopegella

Most microorganisms isolated from low-temperature environments (below 4 degrees C) are eury-, not steno-, psychrophiles. While psychrophiles maximize or maintain growth yield at low temperatures to compensate for low growth rate, the mechanisms involved remain unknown, as does the strategy used by eurypsychrophiles to survive wide ranges of temperatures that include subzero temperatures. Our studies involve the eurypsychrophilic bacterium Psychrobacter cryopegella, which was isolated from a briny water lens within Siberian permafrost, where the temperature is -12 degrees C. P. cryopegella is capable of reproducing from -10 to 28 degrees C, with its maximum growth rate at 22 degrees C. We examined the temperature dependence of growth rate, growth yield, and macromolecular (DNA, RNA, and protein) synthesis rates for P. cryopegella. Below 22 degrees C, the growth of P. cryopegella was separated into two domains at the critical temperature (T(critical) = 4 degrees C). RNA, protein, and DNA synthesis rates decreased exponentially with decreasing temperatures. Only the temperature dependence of the DNA synthesis rate changed at T(critical). When normalized to growth rate, RNA and protein synthesis reached a minimum at T(critical), while DNA synthesis remained constant over the entire temperature range. Growth yield peaked at about T(critical) and declined rapidly as temperature decreased further. Similar to some stenopsychrophiles, P. cryopegella maximized growth yield at low temperatures and did so by streamlining growth processes at T(critical). Identifying the specific processes which result in T(critical) will be vital to understanding both low-temperature growth and growth over a wide range of temperatures.