Isolation and initial characterization of a temperature-sensitive mutant of mouse FM3A cells defective in cytokinesis

A temperature-sensitive mutant, designated tsFT101, was isolated from a mouse mammary carcinoma cell line, FM3A, and given an initial characterization. In this cell line, cytokinesis was blocked at a non-permissive temperature (39 degrees C), but DNA synthesis and nuclear division proceeded normally for at least 24 h at 39 degrees C as detected respectively by autoradiography and cytofluorometric analysis. As a result, multinucleate cells accumulated at 39 degrees C (more than 95% in 36 h). When the culture was returned to a permissive temperature (33 degrees C) after 24 h of arrest at 39 degrees C, cytokinesis was resumed and there was a rapid decrease in the number of multinucleate cells. At 39 degrees C, tsFT101 cells had less F-actin than cells at 33 degrees C, indicative of the existence of an abnormality in actin polymerization in this mutant.     

A temperature-sensitive mutation in asparaginyl-tRNA synthetase causes cell-cycle arrest in early S phase

The Chinese hamster temperature-sensitive cell-cycle mutant ts24 was analyzed biochemically in order to determine the nature of this lesion. The inability of these cells to proceed through S phase at the restrictive temperature could be complemented by the addition of asparagine to the growth medium, and enzymological analysis showed that this line contains a temperature-sensitive asparaginyl-tRNA synthetase. Normal asparaginyl-tRNA synthetase activity was restored in cells transfected with cloned genomic DNA that overcomes the mutational defect. In corroboration with these results it was shown that a different temperature-sensitive asparaginyl-tRNA synthetase mutant isolated in another laboratory was blocked in S phase in a manner similar to that of ts24. While the mechanism by which asparaginyl-tRNA synthetase affects cell-cycle progression has not been elucidated, it can be shown that it is not mediated through alteration in overall levels of protein synthesis.     

An FM3A mutant, G258, with a mutation that affects both cell growth and oligosaccharide-lipid synthesis

I have previously isolated a temperature-sensitive FM3A mutant (G258) defective in asparagine-linked glycosylation. G258 shows not only the temperature sensitivity for cell growth, but also temperature sensitivity for synthesis of oligosaccharide-lipid (Nishikawa, Y. (1984) J. Cell. Physiol. 119, 260-266). In the present study, I isolated revertants for cell growth from G258 cells. All three growth revertants also showed reversion on the synthesis of oligosaccharide-lipid. These results imply that the temperature sensitivity for oligosaccharide-lipid synthesis of G258 couples with the temperature sensitivity for cell growth of the mutant. A possible mechanism of the coupling between impaired oligosaccharide-lipid synthesis and growth arrest of G258 cells at 39 degrees C is discussed.     

The FT210 cell line is a mouse G2 phase mutant with a temperature-sensitive CDC2 gene product

The mouse cell FT210 was isolated as a G2 phase mutant with a possible defect in the histone H1 kinase. We determined that a temperature-sensitive lesion in this cell line lies in the CDC2 gene. DNA sequence analysis revealed two point mutations in highly conserved regions of the gene: an isoleucine to valine change in the PSTAIR region, and a proline to serine change at the C-terminal region of the protein p34. These mutations cause the p34 protein kinase to become inactivated and degraded in FT210 cells at the restrictive temperature, 39 degrees C. The consequence of this temperature-induced inactivation of the CDC2 gene product is cell cycle arrest at the mid to late G2 phase, and this arrest can be alleviated by the introduction of the human CDC2 homolog.     

Constancy of the shift-up point in two temperature-sensitive mammalian cell lines that arrest in G1

Two cell cycle-specific temperature sensitive (ts) mutants of mammalian cell lines, AF8 and K12, are known to arrest in G1 when shifted to the non-permissive temperature. We have determined the entry into S of both AF8 and K12 cells in five different growth conditions, namely: (1) quiescent sparse cultures stimulated to proliferative by serum; (2) quiescent dense cultures stimulated by serum; (3) quiescent sparse cultures stimulated by trypsinization and replating; (4) quiescent, dense cultures stimulated by trypsinization and replating; and (5) mitotic cells collected by mitotic detachment. In addition, for each cell line and for each different growth condition, we have determined the shift-up time, i.e., the time at which a shift-up to the nonpermissive temperature no longer prevents the entry of cells into S. In no case did K12 or AF8 enter S at the nonpermissive temperature. At the permissive temperature, the average time of entry into S varied in different growth conditions, and so did the shift-up time. However, in both cell lines, the distance of the average shift-up time from the average time of entry into S was remarkably constant, regardless of the growth conditions. i.e., 1.8 hours in K12 and 8.6 hours in AF8.     

A point mutation in a cadherin gene, Cdh23, causes deafness in a novel mutant, Waltzer mouse niigata

A novel mouse model for human nonsyndromic hearing loss, Waltzer niigata (v(ngt)), is found and subjected to positional cloning analysis. Genome-wide scan of 1648 backcross mice maps v(ngt) to the D10Mit258 locus near Waltzer (v). Recombination breakpoints are positioned on a physical map consisting of 13 BACs relative to the flanking markers in the vicinity of v(ngt). Allelism test done in parallel shows that v(ngt) and v are allelic. Sequence analysis reveals one-base deletion in the cDNA encoding a cadherin-related protein, Cdh23, mutation of which is recently reported in v mutants. The frame-shift change, producing a truncated protein of 51 amino acids, is ascribed to a base-substitution of G to A in the acceptor site of splicing junction which is predicted to cause one-base shift of the splicing position.     

Low-dose hyper-radiosensitivity: a consequence of ineffective cell cycle arrest of radiation-damaged G2-phase cells

This review highlights the phenomenon of low-dose hyper- radiosensitivity (HRS), an effect in which cells die from excessive sensitivity to small single doses of ionizing radiation but become more resistant (per unit dose) to larger single doses. Established and new data pertaining to HRS are discussed with respect to its possible underlying molecular mechanisms. To explain HRS, a three-component model is proposed that consists of damage recognition, signal transduction and damage repair. The foundation of the model is a rapidly occurring dose-dependent pre-mitotic cell cycle checkpoint that is specific to cells irradiated in the G2phase. This checkpoint exhibits a dose expression profile that is identical to the cell survival pattern that characterizes HRS and is probably the key control element of low-dose radiosensitivity. This premise is strengthened by the recent observation coupling low- dose radiosensitivity of G2-phase cells directly to HRS. The putative role of known damage response factors such as ATM, PARP, H2AX, 53BP1 and HDAC4 is also included within the framework of the HRS model.     

G1 versus G2 cell cycle arrest after adriamycin-induced damage in mouse Swiss3T3 cells

Mutagenesis studies were carried out to examine the effects of replacement of either the nucleophile Glu-236 or the acid/base Glu-128 residue of the F/10 xylanase by a His residue. To our surprise, the affinity for the p-nitrophenyl-beta-D-xylobioside substrate was increased by 10(3)-fold in the case of the mutant E128H enzyme compared with that of the wild-type F/10 xylanase. The catalytic activity of the mutant enzymes was low, despite the fact that the distance between the nucleophilic atom (an oxygen in the native xylanase and a nitrogen in the mutant) and the alpha-carbon was barely changed. Thus, the alteration of the acid/base functionality (Glu-128 to His mutation) provided a significantly favorable interaction within the E128H enzyme/substrate complex in the ground state, accompanying a reduction in the stabilization effect in the transition state.     

Transfer of a mutant viral thymidine kinase gene results in temperature-sensitive mouse cells.

Temperature-sensitive cell lines were obtained by DNA-mediated transfer of the thymidine kinase (TK) gene from a mutant, ts1117, of herpes simplex virus type 1. The cells died at 39 degrees C in selective medium which contained low levels (1 microgram/ml) of thymidine. In this lethal condition, no revertants were detected among 10(8) cells. It was shown by in vitro analysis of the TK activity that the temperature-sensitive cell line contains an enzyme whose activity is temperature sensitive and relatively unaffected by dTTP. The viral enzyme has these properties. The effect of the lethal growth conditions in the cell line was characterized by cell cycle analysis and rescue experiments which involved a shift to the permissive conditions. The successful transfer of the mutant viral TK activity to cells provides an additional selective marker for gene transfer.     

A single homozygous point mutation in a 3'untranslated region motif of selenoprotein N mRNA causes SEPN1-related myopathy

Mutations in the SEPN1 gene encoding the selenoprotein N (SelN) have been described in different congenital myopathies. Here, we report the first mutation in the selenocysteine insertion sequence (SECIS) of SelN messenger RNA, a hairpin structure located in the 3' untranslated region, in a patient presenting a classical although mild form of rigid spine muscular dystrophy. We detected a significant reduction in both mRNA and protein levels in the patient's skin fibroblasts. The SECIS element is crucial for the insertion of selenocysteine at the reprogrammed UGA codon by recruiting the SECIS-binding protein 2 (SBP2), and we demonstrated that this mutation abolishes SBP2 binding to SECIS in vitro, thereby preventing co-translational incorporation of selenocysteine and SelN synthesis. The identification of this mutation affecting a conserved base in the SECIS functional motif thereby reveals the structural basis for a novel pathological mechanism leading to SEPN1-related myopathy.     

A complex degradation signal in Cyclin A required for G1 arrest, and a C-terminal region for mitosis

The destruction box (D-box) consensus sequence has been defined as a motif mediating polyubiquitylation and proteolysis of B-type cyclins during mitosis. We show here that the regions with similarity to D-boxes are not required for mitotic degradation of Drosophila Cyclin A. Instead of a simple D-box, a complex N-terminal degradation signal is present in this cyclin. Mutations that impair or abolish mitotic Cyclin A destruction delay progression through metaphase, but only when overexpressed. Moreover, these mutations prevent epidermal cells from entering the first G1 phase of embryogenesis and lead to a complete extra division cycle instead of a timely cell proliferation arrest. Residual Cyclin A activity after mitosis, therefore, has S phase-promoting activity. In principle, an S phase defect could also explain why epidermal cells fail to enter mitosis 16 in mutants lacking zygotic Cyclin A function. However, we demonstrate that this failure of mitosis is not caused simply by DNA replication or damage checkpoints. Entry into mitosis requires a function of Cyclin A that does not depend on the presence of the N-terminal region.     

A Chinese hamster cell cycle mutant arrested at G2 phase has a temperature-sensitive ubiquitin-activating enzyme, E1

The effect of restrictive temperature on ubiquitin conjugation activity has been studied in cells of ts20, a temperature-sensitive cell cycle mutant of the Chinese hamster cell line E36. Ts20 is arrested in early G2 phase at nonpermissive temperature. Immunoblotting with antibodies to ubiquitin conjugates shows that conjugates disappear rapidly at restrictive temperatures in ts20 mutant but not in wild type E36 cells. The incorporation of 125I-ubiquitin into permeabilized ts20 cells is temperature-sensitive. Addition of extracts of another G2 phase mutant, FM3A ts85, with a temperature-sensitive ubiquitin activation enzyme (E1), to permeabilized ts20 cells at restrictive temperatures fails to complement their ubiquitin ligation activity. This indicates that the lesions in the two mutants are similar. Purified E1 from reticulocytes restores the conjugation activity of heat-inactivated permeabilized ts20 cells. Ubiquitin conjugation activity of cell-free extracts of ts20 cells was temperature-sensitive and could be restored by adding purified reticulocyte E1. Purified reticulocyte E2 or E3, on the other hand, did not restore the ubiquitin conjugation activity of heat-treated ts20 extracts. These results are consistent with the conclusion that ts20 has temperature-sensitive ubiquitin-activating enzyme (E1). The fact that two E1 mutants (ts20 and ts85) derived from different cell lines are arrested at the S/G2 boundary at restrictive temperatures strongly indicates that ubiquitin ligation is necessary for passage through this part of the cell cycle. The temperature thresholds of heat shock protein synthesis of ts20 and wild type E36 cells were identical. The implications of these findings with respect to a suggested role of ubiquitin in coupling between protein denaturation and the heat shock response are discussed.     

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.     

Expression of the noncatalytic domain of the NIMA kinase causes a G2 arrest in Aspergillus nidulans.

Temperature-sensitive mutation of the nimA gene of Aspergillus nidulans causes a reversible G2 arrest, whereas overexpression of nimA causes premature entry into mitosis from which the cells cannot exit. The nimA gene encodes a Ser/Thr-specific protein kinase (NIMA) which contains an extended COOH-terminal noncatalytic domain. To evaluate the role of this enzyme in nuclear division control, we introduced various mutant nimA cDNAs under the control of the inducible alcohol dehydrogenase gene promoter into a strain of Aspergillus nidulans containing a temperature-sensitive nimA mutation (nimA5). While expression of the wild type NIMA complemented the nimA5 mutation and induced a premature mitotic arrest when overexpressed, expression of a kinase-negative NIMA containing a single amino acid mutation in the putative ATP-binding site could not rescue the nimA5 mutation but resulted in a specific G2 arrest when overexpressed. An identical phenotype was observed with cells expressing only the noncatalytic COOH-terminal domain of NIMA, whereas overexpression of the inactive kinase domain was without effect. The G2 arrest produced by overexpression of the full-length inactive or COOH-terminal NIMA molecules did not prevent activation of the endogenous NIMA or H1 kinase activity precipitable by p13 beads. We suggest that this dominant-negative phenotype results from competitive inhibition of the association of active NIMA with a cellular target(s) and that appropriate targeting is essential for the mitotic function of the NIMA kinase.     

Glycolipid composition of a mutant cell line of mouse FM3A cells, and the effect of exogenous glycolipids on cell growth

Had-1 isolated from mouse mammary tumour FM3A cells as a non-permissive cell line to Newcastle disease virus infection is deficient in NDV receptors, and galactosylation of the complex type sugar chains of the glycoproteins is extensively reduced compared to FM3A cells. It is also deficient in UDP-galactose transport into Golgi vesicles. The major neutral glycolipids in FM3A is Lac-Cer, whereas, in Had-1 cell, Glc-Cer is the major glycolipid and the concentration of neutral glycolipids is one-tenth as low as that in FM3A. GM3, GD3 and sialyl i- and I-type lactosaminylceramide are the gangliosides present in both FM3A and Had-1, although their presence in both cells is only in traces. Had-1 contains relatively high N-glycolyl-neuraminic acid. Among the several glycolipids tested, Lac-Cer, Gg-4-Cer and Glc-Cer showed inhibitory effect on proliferation of Had-1 cells, but did not show any appreciable effect on that of FM3A cells. Lac-Cer had the most potent inhibitory effect and this inhibitory effect was completely reversible. While mice injected with 5 x 10(6) cells of FM3A died in one month, those injected of Had-1 cells at the same dose survived for more than 6 months. Thus glycolipids on the cell surface play an essential role during cell growth both in vivo and in vitro.     

Preliminary characterization of the temperature-sensitive defect in DNA replication in a mutant mouse L cell

Temperature-sensitive ts A1S9 mouse L cells synthesize DNA apparently normally for 6–8 hr upon incubation at 38.5°C. Thereafter, these cells are able to perform limited polydeoxyribonucleotide chain synthesis at the high temperature, but are unable to convert newly replicated small single-strand segments of DNA (of the order of molecular weight 10⁶ daltons) to large molecular weight chromosomal DNA. Data obtained are compatible with a model which suggests that ts A1S9 cells are able to carry out most individual reactions of DNA synthesis at the high temperature, but are temperature-sensitive in a protein which participates in the joining of small DNA segments to make chromosomal DNA strands. When cells are reincubated at a permissive temperature, after the temperature-sensitive lesion has been established, they recover the latter capability several hours before they are able once again to synthesize DNA at normal rates.     

Isolation, characterisation and molecular cloning of new mutant alleles of the fission yeast p34cdc2+ protein kinase gene: identification of temperature-sensitive G2-arresting alleles

Summary The protein serine-threonine kinase p34 ^cdc2+ plays a central role in the control of the mitotic cell cycle of the fission yeast Schizosaccharomyces pombe. p34 ^cdc2+ function is required both for the initiation of DNA replication and for entry into mitosis, and is also required for the initiation of the second meiotic nuclear division. Recent extensive analysis of p34 ^cdc2+ homologue proteins in higher eukaryotes has demonstrated that p34 ^cdc2+ function is likely to be conserved in all eukaryotic cells. Here we report the isolation and characterisation of five new temperature-sensitive alleles of the cdc ²⁺ gene. All five have been cloned and sequenced, together with the meiotically defective cdc2-N22 allele, bringing the total of p34 ^cdc2+ mutants cloned in this and previous reports to seventeen. The five temperature-sensitive alleles define four separate mutations within the p34 ^cdc2+ protein sequence, two of which give rise to cell cycle arrest in G₂ only, when shifted to the restrictive temperature. The nature of the mutation in each protein is described and possible implications for the structure and function of p34 ^cdc2+ discussed.     

Establishment of mutant murine mammary carcinoma FM3A cell strains transformed with the herpes simplex virus type 2 thymidine kinase gene

To establish cell systems appropriate for investigating the mode of action of antiherpetic nucleoside analogues, mutant cell strains were constructed from murine mammary carcinoma FM3A cells, which were deficient in TK, but were transformed with a recombinant plasmid DNA containing the HSV-2 TK gene. The transformed cells incorporated the viral DNA, expressed viral TK activity and showed unusually high sensitivity to the cytostatic action of the antiherpetic nucleoside analogues ACV and IVDU, both of which were only weakly inhibitory to the growth of the parent cells. Curiously, the FM3A cell strains transformed with HSV-2 TK gene showed a higher sensitivity to ACV and IVDU than the previously established cell line transformed with HSV-1 TK gene. This contrasts with the inhibitory effects of ACV and IVDU on acute HSV infection, since HSV-2 infection is slightly or considerably less susceptible than HSV-1 infection to inhibition by ACV or IVDU, respectively.     

The cdc30 mutation in Saccharomyces cerevisiae results in a temperature-sensitive isoenzyme of phosphoglucose isomerase

The cdc30 mutation in the yeast Saccharomyces cerevisiae causes cell cycle arrest late in nuclear division when cells are shifted from the permissive temperature of 25 degrees C to the restrictive temperature of 36.5 degrees C. Cell cycle arrest at 36.5 degrees C is dependent upon the carbon source used: a shift-up in glucose containing media results in cell cycle blockade, whereas a shift-up in ethanol, fructose, glycerol, glycerol plus ethanol, or mannose does not. Metabolite analyses showed accumulation of glucose 6-phosphate in a cdc30-bearing strain after a temperature shift-up in glucose-containing medium. Thermal denaturation studies and kinetic measurements indicate the existence of two isoenzymes of phosphoglucose isomerase (EC 5.3.1.9); one of which is apparently altered in the temperature-sensitive cell cycle mutant. We propose that the gene products of both the CDC30 and PG11 genes are required for cell cycle progression in glucose media and that the PGI1 gene product has a regulatory function over the CDC30 gene product.