Cell cycle arrest in Era GTPase mutants: a potential growth rate-regulated checkpoint in Escherichia coli

Era is a low-molecular-weight GTPase essential for Escherichia coli viability. The gene encoding Era is found in the rnc operon, and the synthesis of both RNase III and Era increases with growth rate. Mutants that are partially defective in Era GTPase activity or that are reduced in the synthesis of wild-type Era become arrested in the cell cycle at the predivisional two-cell stage. The partially defective Era GTPase mutation ( era1 ) suppresses several temperature-sensitive lethal alleles that affect chromosome replication and chromosome partitioning but not cell division. Our results suggest that Era plays an important role in cell cycle progression at a specific point in the cycle, after chromosome partitioning but before cytokinesis. Possible functions for Era in cell cycle progression and the initiation of cell division are discussed.     

Suppression of defective ribosome assembly in a rbfA deletion mutant by overexpression of Era,an essential GTPase in Escherichia coli

Era is a small GTP-binding protein and essential for cell growth in Escherichia coli. It consists of two domains: N-terminal GTP-binding and C-terminal RNA-binding KH domains. It has been shown to bind to 16S rRNAs and 30S ribosomal subunits in vitro. Here, we report that a precursor of 16S rRNA accumulates in Era-depleted cells. The accumulation of the precursors is also seen in a cold-sensitive mutant, E200K, in which the mutation site is located in the C-terminal domain. The major precursor molecule accumulated seems to be 17S rRNA, containing extra sequences at both 5' and 3' ends of 16S rRNA. Moreover, the amounts of both 30S and 50S ribosomal subunits relative to the amount of 70S monosomes increase in Era-depleted and E200K mutant cells. The C-terminal KH domain has a high structural similarity to the RbfA protein, a cold shock protein that also specifically associates with 30S ribosomal subunits. RbfA is essential for cell growth at low temperature, and a precursor of 16S rRNA accumulates in an rbfA deletion strain. The 16S rRNA precursor seems to be identical in size to that accumulated in Era mutant cells. Surprisingly, the cold-sensitive cell growth of the rbfA deletion cells was partially suppressed by overproduction of the wild-type Era. The C-terminal domain alone was not able to suppress the cold-sensitive phenotype, whereas Era-dE, which has a 10-residue deletion in a putative effector region of the N-terminal domain, functioned as a more efficient suppressor than the wild-type Era. It was found that Era-dE suppressed defective 16S rRNA maturation, resuming a normal polysome profile to reduce highly accumulated free 30S and 50S subunits in the rbfA deletion cells. These results indicate that Era is involved in 16S rRNA maturation and ribosome assembly.     

Cellular defects caused by deletion of the Escherichia coli dnaK gene indicate roles for heat shock protein in normal metabolism.

DnaK is a major heat shock protein of Escherichia coli and has been previously reported to be essential for growth at high temperatures. We systematically investigated the role of DnaK in cellular metabolism at a wide range of growth temperatures by analyzing cellular defects caused by deletion of the dnaK gene (delta dnaK52). At intermediate temperatures (30 degrees C), introduction of the delta dnaK52 allele into wild-type cells caused severe defects in cell division, slow growth, and poor viability of the cells. delta dnaK52 mutants were genetically unstable at 30 degrees C and frequently acquired secondary mutations. At high (42 degrees C) and low (11 and 16 degrees C) temperatures the delta dnaK52 allele could only be introduced into the subpopulation of wild-type cells that had duplicated the dnaK region of their chromosome. delta dnaK52 mutants isolated at 30 degrees C were cold sensitive as well as temperature sensitive for growth. Cell division defects of delta dnaK52 mutants at 30 degrees C were largely suppressed by overproduction of the FtsZ protein, which is normally required for septation during cell division; however, slow growth and poor viability at 30 degrees C and cold sensitivity and temperature sensitivity of growth were not suppressed, indicating that delta dnaK52 mutants had additional defective cellular functions besides cell division.     

Characterization of mutations affecting the Escherichia coli essential GTPase era that suppress two temperature-sensitive dnaG alleles.

Two suppressor mutations of the temperature-sensitive DNA primase mutant dnaG2903 have been characterized. The gene responsible for suppression, era, encodes an essential GTPase of Escherichia coli. One mutation, rnc-15, is an insertion of an IS1 element within the leader region of the rnc operon and causes a polar defect on the downstream genes of the operon. A previously described polar mutation, rnc-40, was also able to suppress dnaG2903. The other mutation, era-1, causes a single amino acid substitution (P17R) in the G1 region of the GTP-binding domain of Era. Analysis of the GTPase activity of the Era-1 mutant protein showed a four- to five-fold decrease in the ability to convert GTP to GDP. Thus, lowered expression of wild-type Era caused by the polar mutations and reduced GTPase activity caused by the era-1 mutation suppresses dnaG2903 as well as a second dnaG allele, parB. Phenotypic analysis of the era-1 mutant at 25 degrees C showed that 10% of the cells contain four segregated nucleoids, indicative of a delay in cell division. Possible mechanisms of suppression of dnaG and roles for Era are discussed.     

Era and RbfA have overlapping function in ribosome biogenesis in Escherichia coli

A cold-shock protein, RbfA (ribosome-binding factor A), is essential for cell growth at low temperature. In an rbfA-deletion strain, 30S and 50S ribosomal subunits increase relative to 70S monosomes with concomitant accumulation of a precursor 16S rRNA (17S rRNA). Recently, we have reported that overexpression of Era, an essential GTP-binding protein, suppresses not only the cold-sensitive cell growth but also defective ribosome biogenesis in the rbfA-deletion strain. Here, in order to elucidate how RbfA and Era functionally overlap, we characterized a cold-sensitive Era mutant (a point mutation at the Glu-200 to Lys; E200K) which shows a similar phenotype as the rbfA-deletion strain; accumulation of free ribosome subunits and 17S rRNA. To examine the effect of E200K in the rbfA-deletion strain, we constructed an E200K-inducible expression system. Interestingly, unlike wild-type Era, overexpression of Era(E200K) protein in the rbfA-deletion strain severely inhibited cell growth even at permissive temperature with further concomitant reduction of 16S rRNA. Purified Era(E200K) protein binds to 30S ribosomal subunits in a nucleotide-dependent manner like wild-type Era and retains both GTPase and autophosphorylation activities. Furthermore, we isolated spontaneous revertants of the E200K mutant. These revertants partially suppressed the accumulation of 17S rRNA. All the spontaneous mutations were found to result in higher Era(E200K) expression. These results suggest that the Era(E200K) protein has an impaired function in ribosome biogenesis without losing its ribosome binding activity. The severe growth defect caused by E200K in the rbfA-deletion strain may be due to competition between intrinsic wild-type Era and overexpressed Era(E200K) for binding to 30S ribosomal subunits. We propose that Era and RbfA have an overlapping function that is essential for ribosome biogenesis, and that RbfA becomes dispensable only at high temperatures because Era can complement its function only at higher temperatures.     

A role for the common GTP-binding protein in coupling of chromosome replication to cell growth and cell division

Homologues of CgtA, the common GTP-binding protein of Vibrio harveyi, are present in diverse organisms ranging from bacteria to humans. In bacteria, proteins homologous to CgtA form a subfamily of small GTP-binding proteins, called Obg/Gtp1. Similarity between bacterial members of this subfamily and their eukaryotic homologues is as high as about 50%. Nevertheless, specific functions of these proteins remain largely unknown. Genes coding for CgtA-like proteins are essential in almost all species of bacteria. The only known exception is V. harveyi, whose cells survive disruption of the cgtA gene. Therefore, the V. harveyi cgtA insertional mutant is a very useful tool for studies on functions of CgtA. Here we demonstrate that under normal growth conditions, cells of the cgtA mutant are slightly larger than wild-type cells, whereas indirect inhibition of DNA replication initiation by addition of rifampicin results in significantly higher differences in average cell size between these two strains as measured by flow cytometry. These differences decreased when cell division was inhibited by cephalexin. DNA synthesis per cell mass was found to be increased in the cgtA mutant relative to wild-type V. harveyi strain, whereas the mutant cells grew slower than bacteria with functional cgtA gene. Kinetics of DNA replication after inhibition of cell division was also considerably different in wild-type and cgtA mutant strains. These results suggest that the cgtA gene product plays a role in coupling of DNA replication to cell growth and cell division.     

Cold-sensitive growth and decreased GTP-hydrolytic activity from substitution of Pro17 for Val in Era, an essential Escherichia coli GTPase

A substitution mutation of Pro17 by Val (P17V) was constructed in the guanine nucleotide binding domain of Era, an essential protein in Escherichia coli. The mutation is analogous to the oncogenic activating allele at position 12 in the GTP-binding domain of p21ras. The phenotype of this mutant was analysed in a strain which exclusively expressed the mutant protein (Era-V17) in null allele chromosomal background (era1: :kan). The strain was found to be cold-sensitive for growth. Mutant Era-V17 purified from the strain was cold-sensitive for GTP-hydrolytic activity, suggesting that the GTPase activity of Era is required for cell growth since the P17V mutation resulted in both cold-sensitive growth of cells and cold-labile GTPase activity of the purified protein.     

Streptococcus faecium mutants that are temperature sensitive for cell growth and show alterations in penicillin-binding proteins.

The penicillin-binding proteins (PBPs) of 209 cell division (or growth) temperature-sensitive mutants of Streptococcus faecium were analyzed in this study. A total of nine strains showed either constitutive or temperature-sensitive conditional damage in the PBPs. Analysis of these nine strains yielded the following results: one carried a PBP 1 constitutively showing a lower molecular weight; one constitutively lacked PBP 2; two lacked PBP 3 at 42 degrees C, but not at 30 degrees C; one was normal at 30 degrees C but at 42 degrees C lacked PBP 3 and overproduced PBP 5; two were normal at 42 degrees C and lacked PBP 5 at 30 degrees C; one constitutively lacked PBP 5; and one carried a PBP 6 constitutively split in two bands. The mutant lacking PBP 3 and overproducing PBP 5 continued to grow at 42 degrees C for 150 min and then lysed. Revertants selected for growth capability at 42 degrees C from the mutants altered in PBPs 5 and 6 maintained the same PBP alterations, while those isolated from the strains with altered PBP 1 or lacking PBP 2 or PBP 3 showed a normal PBP pattern. Penicillin-resistant derivatives were isolated at 30 degrees C from the mutants lacking PBP 2 and from that lacking PBP 3. All these derivatives continued to show the same PBP damage as the parents, but overproduced PBP 5 and grew at 42 degrees C. These findings indicate that high-molecular-weight, but not low-molecular-weight, PBPs are essential for cell growth in S. faecium. This is in complete agreement with previous findings obtained with a different experimental system. On the basis of both previous and present data it is suggested that PBPs 1, 2, and 3 appear necessary for cell growth at optimal temperature (and at maximal rate), but not for cell growth at a submaximal one (or at a reduced rate), and an overproduced PBP 5 is capable of taking over the function of PBPs 1, 2, and 3.     

Induction of cell division in a temperature-sensitive division mutant of Escherichia coli by inhibition of protein synthesis.

Synchronous cells of the thermosensitive division-defective Escherichia coli strain MACI (divA) divided at the restrictive temperature (42 degrees C) if they were allowed to grow at 42 degrees C for a certain period before protein synthesis was inhibited by adding chloramphenicol (CAP) or rifampicin. The completion of chromosome replication was not required for such divA-independent division. Synchronous cells of strain MACI divided in the presence of an inhibitor of DNA synthesis, nalidixic acid, if they were shifted to 42 degrees C and CAP or rifampicin was added after some time; cells of the parent strain MC6 (div A+) treated in the same way did not divide. These data suggest that coupling of cell division to DNA synthesis depends on the divA function. The ability to divide at 42 degrees C, whether or not chromosome termination was allowed, was directly proportional to the mean cell volume of cultures at the time of CAP addition, suggesting that cells have to be a certain size to divide under these conditions. The period of growth required for CAP-induced division had to be at the restrictive temperature; when cells were grown at 30 degrees C, in the presence of nalidixic acid to prevent normal division, they did not divide on subsequent transfer to 42 degrees C followed, after a period, by protein synthesis inhibition. A model is proposed in which the role of divA as a septation initiator gene is to differentiate surface growth sites by converting a primary unregulated structure, with the capacity to make both peripheral wall and septum, to a secondary structure committed to septum formation.     

Survival of Flavobacterium psychrophilum in rainbow trout (Oncorhynchus mykiss) serum in vitro

Virulent and non-virulent strains of Flavobacterium psychrophilum of different serotypes were examined for survival and growth in non-immune and immune rainbow trout serum, in vitro. A majority of the examined strains consumed complement of non-immune serum, but the complement cascade was not able to cause an immediate (after 3 h incubation) notable reduction in viability of the inoculated cells. After 24 h incubation a more pronounced reduction in the number of viable bacteria was observed in untreated serum as well as in serum heated at 45 degrees C. In serum heated at 56 degrees C this reduction in cell number was not observed, but an increase in cell number did not occur either. The serum survival of one of the examined strains was different from the others in showing cell multiplication after 24 h incubation in normal as well as heat-treated (45 and 56 degrees C) serum. In immune serum no immediate reduction in viability of inoculated cells, of all tested strains, was observed. The number of viable cells showed a slow decrease or remained almost unchanged for up to 72 h post-inoculation in untreated serum, at 5 degrees C as well as 15 degrees C. In heat-treated serum (45 degrees C) the number of viable cells decreased slowly at 5 degrees C and 15 degrees C for up to 72 h. The results suggest that the examined strains were unaffected by the alternative complement reaction present in fish serum as well as by antibodies against F. psychrophilum. However, some unknown component(s) in the fish sera, or lack of nutrients or essential growth factors, inhibited the growth of most of the examined strains in the tested fish sera.     

The Gene for 16S rRNA Methyltransferase (ksgA) Functions as a Multicopy Suppressor for a Cold-Sensitive Mutant of Era, an Essential RAS-Like GTP-Binding Protein in Escherichia coli

Era, a Ras-like GTP-binding protein in Escherichia coli, has been shown to be essential for growth. However, its cellular functions still remain elusive. In this study, a genetic screening of an E. coli genomic library was performed to identify those genes which can restore the growth ability of a cold-sensitive mutant, Era(Cs) (E200K), at a restrictive temperature when expressed in a multicopy plasmid. Among eight suppressors isolated, six were located at 1 min of the E. coli genomic map, and the gene responsible for the suppression of Era(Cs) (E200K) was identified as the ksgA gene for 16S rRNA transmethylase, whose mutation causes a phenotype of resistance to kasugamycin, a translation initiation inhibitor. This is the first demonstration of suppression of impaired function of Era by overproduction of a functional enzyme. A possible mechanism of the suppression of the Era cold-sensitive phenotype by KsgA overproduction is discussed.     

New temperature-sensitive alleles of ftsZ in Escherichia coli

We isolated five new temperature-sensitive alleles of the essential cell division gene ftsZ in Escherichia coli, using P1-mediated, localized mutagenesis. The five resulting single amino acid changes (Gly109-->Ser109 for ftsZ6460, Ala129-->Thr129 for ftsZ972, Val157-->Met157 for ftsZ2066, Pro203-->Leu203 for ftsZ9124, and Ala239-->Val239 for ftsZ2863) are distributed throughout the FtsZ core region, and all confer a lethal cell division block at the nonpermissive temperature of 42 degrees C. In each case the division block is associated with loss of Z-ring formation such that fewer than 2% of cells show Z rings at 42 degrees C. The ftsZ9124 and ftsZ6460 mutations are of particular interest since both result in abnormal Z-ring formation at 30 degrees C and therefore cause significant defects in FtsZ polymerization, even at the permissive temperature. Neither purified FtsZ9124 nor purified FtsZ6460 exhibited polymerization when it was assayed by light scattering or electron microscopy, even in the presence of calcium or DEAE-dextran. Hence, both mutations also cause defects in FtsZ polymerization in vitro. Interestingly, FtsZ9124 has detectable GTPase activity, although the activity is significantly reduced compared to that of the wild-type FtsZ protein. We demonstrate here that unlike expression of ftsZ84, multicopy expression of the ftsZ6460, ftsZ972, and ftsZ9124 alleles does not complement the respective lethalities at the nonpermissive temperature. In addition, all five new mutant FtsZ proteins are stable at 42 degrees C. Therefore, the novel isolates carrying single ftsZ(Ts) point mutations, which are the only such strains obtained since isolation of the classical ftsZ84 mutation, offer significant opportunities for further genetic characterization of FtsZ and its role in cell division.     

Characterization of the autophosphorylation of Era, an essential Escherichia coli GTPase

Era is an essential protein in Escherichia coli which binds both GTP and GDP and has an intrinsic GTPase activity. Studies on the role of GTP/GDP binding and GTPase activity in an attempt to understand its function lead to the observation that Era is autophosphorylated. The autophosphorylated reaction is specific for GTP and cannot use ATP as a phosphoryl group donor. The reaction velocity is of first order with respect to protein concentration, suggesting an intramolecular mechanism. Autophosphorylation occurs at serine and threonine residues. The major phosphorylated tryptic peptide isolated after autophosphorylation has been identified as ISITSR, from residue 33 to 38. The peptide contains the site of phosphorylation and two potential sites for serine and threonine phosphorylation. Subsequently, both the threonine residue at position 36 and the serine residue at position 37 were altered to alanine. The double mutant Era, but not individual single mutants, was unable to functionally complement the growth of an E. coli strain which cannot produce wild-type Era protein at high temperature. This suggests that either threonine 36 or serine 37 has to exist for the function of Era In vivo. phosphorylation of Era was also examined by two-dimensional gel electrophoresis. Era has been previously assigned two distinct positions having two different X-Y co-ordinates: one of the spots (H032.0) was identified as phosphorylated Era, indicating that a substantial portion of Era in the cell is indeed phosphorylated. Therefore, Era autophosphorylation is likely to play an important physiological role in the cell. The sequence encoding the C-terminus previously published had a missing C between A900 and GgO1. As a resuit of the frameshift, Era consists of 301 residues, 15 fewer than originaiiy reported.     

Nitrogen regulation of urease synthesis in Saccharopolyspora erythraea ATCC 11365

Abstract Era is an essential GTP-binding protein of an unknown function in Escherichia coli . On the basis of its sequence similarities to other GTP-binding proteins such as E. coli EF-Tu, EF-G, IF2 and eukaryotic Ras proteins, it has been suggested that the Era function is activated by GTP binding, and that subsequent conversion of bound GTP to GDP by the intrinsic GTPase activity modulates its function. Two Era mutants, one dominant negative mutant (dE), which has a deletion mutation from Ala40 to Gly49, and the other non-functional mutant (T42A/T43A), which has two substitution mutations, Thr42 to Ala and Thr43 to Ala, were analyzed for their abilities of GTP-binding and GTPase activity. It was found that the dE mutant lost the GTP-binding ability, while it still retained the GTPase activity. On the other hand, the T42A/T43A mutant retained both the GTP-crosslinking and GTPase activities. However, the K _m values for GTPase activity increased 5-and 12-fold for dE and T42A/T43A mutants, respectively. These results indicate that both the GTP-binding and GTPase activities are important for the Era function.     

Delta dnaK52 mutants of Escherichia coli have defects in chromosome segregation and plasmid maintenance at normal growth temperatures.

Major heat shock proteins, such as the Escherichia coli DnaK protein, not only are required for cell growth after heat shock but seem to possess important functions in cellular metabolism at normal growth temperatures as well. E. coli delta dnaK52 mutants have severe cellular defects at 30 degrees C, one of which is in cell division (B. Bukau and G. C. Walker, J. Bacteriol, 171:2337-2346, 1989). Here we show that at 30 degrees C, delta dnaK52 mutants have defects in chromosome segregation and in maintenance of low-copy-number plasmids. Fluorescence microscopic analysis revealed that chromosomes were frequently lacking at peripheries of cell filaments of delta dnaK52 mutants and clustered at other locations. In other parts of the cell filaments, chromosomes were apparently normally distributed and they were also present in most of the small cells found in populations of delta dnaK52 cells. These defects might be at the level of DNA replication, since delta dnaK52 mutants have a threshold lower rate of DNA synthesis than wild-type cells. Chromosome segregation defects of delta dnaK52 mutants were also observed in an rnh dnaA mutant background, in which initiation of DNA replication is DnaA-oriC independent. We also found that low-copy-number P1 miniplasmids could not be stably maintained in delta dnaK52 mutants at 30 degrees C. delta par P1 miniplasmids that carry the P1-encoded rep functions required for their replication but lack the P1-encoded par functions required for faithful partitioning of the plasmids during cell division were also unstable in delta dnaK52 mutants. Taken together, our results indicate important, although not absolutely essential, functions for DnaK at 30 degrees C in one or more processes necessary for correct replication and/or partitioning of chromosomes and P1 miniplasmids. Furthermore, we found that P1 miniplasmids were also highly unstable in dnaJ259 mutants, indicating a role for the DnaJ heat shock protein in maintenance of these plasmids.     

Characterization of mutations in the GTP-binding domain of IF2 resulting in cold-sensitive growth of Escherichia coli

The infB gene encodes translation initiation factor IF2. We have determined the entire sequence of infB from two cold-sensitive Escherichia coli strains IQ489 and IQ490. These two strains have been isolated as suppressor strains for the temperature-sensitive secretion mutation secY24. The mutations causing the suppression phenotype are located within infB. The only variations from the wild-type (wt) infB found in the two mutant strains are a replacement of Asp409 with Glu in strain IQ489 and an insertion of Gly between Ala421 and Gly422 in strain IQ490. Both positions are located in the GTP-binding G-domain of IF2. A model of the G-domain of E.coli IF2 is presented in. Physiological quantities of the recombinant mutant proteins were expressed in vivo in E.coli strains from which the chromosomal infB gene has been inactivated. At 42 degrees C, the mutants sustained normal cell growth, whereas a significant decrease in growth rate was found at 25 degrees C for both mutants as compared to wt IF2 expressed in the control strain. Circular dichroism spectra were recorded of the wt and the two mutant proteins to investigate the structural properties of the proteins. The spectra are characteristic of alpha-helix dominated structure, and reveal a significant different behavior between the wt and mutant IF2s with respect to temperature-induced conformational changes. The temperature-induced conformational change of the wt IF2 is a two-state process. In a ribosome-dependent GTPase assay in vitro the two mutants showed practically no activity at temperatures below 10 degrees C and a reduced activity at all temperatures up to 45 degrees C, as compared to wt IF2. The results indicate that the amino acid residues, Asp409 and Gly422, are located in important regions of the IF2 G-domain and demonstrate the importance of GTP hydrolysis in translation initiation for optimal cell growth.     

Pleiotropic changes resulting from depletion of Era, an essential GTP-binding protein in Escherichia coli

Phenotypic analysis of a temperature-sensitive era mutant strain indicates that Escherichia coli cells depleted of Era undergo many physiological changes. At 43 degrees C, a completely non-permissive temperature, growth is arrested because of loss of the gene and depletion of the Era protein. Depletion of Era at 43 degrees C results in depressed synthesis of heat-shock proteins DnaK, GroEL/ES, D33.4 and C62.5, lack of thermal induction of ppGpp pool levels, and increased capacity for carbon source metabolism through the citric acid cycle. Thus, in addition to inhibition of cell growth and viability, loss of Era function results in pleiotropic changes including abnormal adaptation to thermal stress.     

Temperature-Sensitive Cell Division Mutants of Escherichia coli with Thermolabile Penicillin-Binding Proteins

The thermostability of the penicillin-binding proteins (PBPs) of 31 temperature-sensitive cell division mutants of Escherichia coli has been examined. Two independent cell division mutants have been found that have highly thermolabile PBP3. Binding of [(14)C]benzylpenicillin to PBP3 (measured in envelopes prepared from cells grown at the permissive temperature) was about 30% of the normal level at 30 degrees C, and the ability to bind [(14)C]benzylpenicillin was rapidly lost on incubation at 42 degrees C. The other PBPs were normal in both mutants. At 30 degrees C both mutants were slightly longer than their parents and on shifting to 42 degrees C they ceased dividing, but cell mass and deoxyribonucleic acid synthesis continued and long filaments were formed. At 42 degrees C division slowly recommenced, but at 44 degrees C this did not occur. The inhibition of division at 42 degrees C was suppressed by 0.35 M sucrose, and in one of the mutants it was partially suppressed by 10 mM MgCl(2). PBP3 was not stabilized in vitro at 42 degrees C by these concentrations of sucrose or MgCl(2). Revertants that grew as normal rods at 42 degrees C regained both the normal level and the normal thermostability of PBP3. The results provide extremely strong evidence that the inactivation of PBP3 at 42 degrees C in the mutants is the cause of the inhibition of cell division at this temperature and identify PBP3 as an essential component of the process of cell division in E. coli. It is the inactivation of this protein by penicillins and cephalosporins that results in the inhibition of division characteristic of low concentrations of many of these antibiotics.     

Cell cycle dependence of transformation expression in mouse cells transformed by a thermosensitive mutant (Ts-121) of polyoma virus.

Change in division capability as a phenotypic expression of cellular transformation was investigated by using one of the temperature-sensitive (ts) mutants of the polyoma virus-transformed cell line, the 121-6-5 cells of BALB/3T3. When contact -inhibited cells were treated with hyaluronidase at 39 degrees C, a single round of cell division was induced after which cell growth was inhibited by cell density. However, if the cells were incubated at 35 degrees C, after the enzyme treatment, density-inhibition block disappeared and the cells entered a second division. This indicates that the release of cells from density-inhibition depends on the low temperature incubation. The ability of cells to complete a second division was examined by shifting the cells from 39 degrees C to 35 degrees C during different phases of the first division cycle after the enzyme-treatment. A 6-hour incubation of S phase cells at 35 degrees C resulted in a second cycle of division, while the 24-hour incubation of G1 cells at 35 degrees C did not induce a second round of division. These results suggest that expression of the transformed phenotype in 121-6-5 cells is clearly dependent upon both the temperature and the phase of the division cycle.