Linkage of the MBG locus to another functionally hemizygous gene locus (IDH2) on chromosome Z3 in Chinese hamster ovary cells

Recent advances in the molecular biology of metazoan polyamine transport

Very limited molecular knowledge exists about the identity and protein components of the ubiquitous polyamine transporters found in animal cells. However, a number of reports have been published over the last 5 years on potential candidates for metazoan polyamine permeases. We review the available evidence on these putative polyamine permeases, as well as establish a useful "identikit picture" of the general polyamine transport system, based on its properties as found in a wide spectrum of mammalian cells. Any molecular candidate encoding a putative "general" polyamine permease should fit that provided portrait. The current models proposed for the mechanism of polyamine internalization in mammalian cells are also briefly reviewed.

Newly identified CHO ERCC3/XPB mutations and phenotype characterization

Nucleotide excision repair (NER) is a complex multistage process involving many interacting gene products to repair a wide range of DNA lesions. Genetic defects in NER cause human hereditary diseases including xeroderma pigmentosum (XP), Cockayne syndrome (CS), trichothiodystrophy and a combined XP/CS overlapping symptom. One key gene product associated with all these disorders is the excision repair cross-complementing 3/xeroderma pigmentosum B (ERCC3/XPB) DNA helicase, a subunit of the transcription factor IIH complex. ERCC3 is involved in initiation of basal transcription and global genome repair as well as in transcription-coupled repair (TCR). The hamster ERCC3 gene shows high degree of homology with the human ERCC3/XPB gene. We identified new mutations in the Chinese hamster ovary cell ERCC3 gene and characterized the role of hamster ERCC3 protein in DNA repair of ultraviolet (UV)-induced and oxidative DNA damage. All but one newly described mutations are located in the protein C-terminal region around the last intron-exon boundary. Due to protein truncations or frameshifts, they lack amino acid Ser751, phosphorylation of which prevents the 5' incision of the UV-induced lesion during NER. Thus, despite the various locations of the mutations, their phenotypes are similar. All ercc3 mutants are extremely sensitive to UV-C light and lack recovery of RNA synthesis (RRS), confirming a defect in TCR of UV-induced damage. Their limited global genome NER capacity averages approximately 8%. We detected modest sensitivity of ercc3 mutants to the photosensitizer Ro19-8022, which primarily introduces 8-oxoguanine lesions into DNA. Ro19-8022-induced damage interfered with RRS, and some of the ercc3 mutants had delayed kinetics. All ercc3 mutants showed efficient base excision repair (BER). Thus, the positions of the mutations have no effect on the sensitivity to, and repair of, Ro19-8022-induced DNA damage, suggesting that the ERCC3 protein is not involved in BER.

TATA-binding protein-associated factor 7 regulates polyamine transport activity and polyamine analog-induced apoptosis

Identification of the polyamine transporter gene will be useful for modulating polyamine accumulation in cells and should be a good target for controlling cell proliferation. Polyamine transport activity in mammalian cells is critical for accumulation of the polyamine analog methylglyoxal bis(guanylhydrazone) (MGBG) that induces apoptosis, although a gene responsible for transport activity has not been identified. Using a retroviral gene trap screen, we generated MGBG-resistant Chinese hamster ovary (CHO) cells to identify genes involved in polyamine transport activity. One gene identified by the method encodes TATA-binding protein-associated factor 7 (TAF7), which functions not only as one of the TAFs, but also a coactivator for c-Jun. TAF7-deficient cells had decreased capacity for polyamine uptake (20% of CHO cells), decreased AP-1 activation, as well as resistance to MGBG-induced apoptosis. Stable expression of TAF7 in TAF7-deficient cells restored transport activity (55% of CHO cells), AP-1 gene transactivation (100% of CHO cells), and sensitivity to MGBG-induced apoptosis. Overexpression of TAF7 in CHO cells did not increase transport activity, suggesting that TAF7 may be involved in the maintenance of basal activity. c-Jun NH2-terminal kinase inhibitors blocked MGBG-induced apoptosis without alteration of polyamine transport. Decreased TAF7 expression, by RNA interference, in androgen-independent human prostate cancer LN-CaP104-R1 cells resulted in lower polyamine transport activity (25% of control) and resistance to MGBG-induced growth arrest. Taken together, these results reveal a physiological function of TAF7 as a basal regulator for mammalian polyamine transport activity and MGBG-induced apoptosis.

Studies on mammalian mutants defective in rejoining double-strand breaks in DNA

Mutants with defects in the rejoining of DNA double-strand breaks (dsbs) have been identified and characterised from E. coli and the yeast, Saccharomyces cerevisiae. More recently, 3 mammalian cell mutants with defective dsb rejoining have also been described. These mutants are xrs, XR-1 and L5178Y/S, and they are derived from at least two distinct complementation groups. The aim of this article is to review the current status of the studies with these mammalian cell mutants which are defective in dsb rejoining and, in particular, to compare their properties with those mutants identified from lower organisms. Possible mechanistic differences in the process of dsb rejoining between prokaryotes and lower and higher eukaryotes are discussed. All the mammalian mutants defective in dsb rejoining, are sensitive primarily to ionising radiation with little cross-sensitivity to UV-radiation. This is similar to the rad52 mutants of S. cerevisiae but contrasts to the majority of the E. coli mutants with defective dsb rejoining. Where studied, the mammalian cell mutants show enhanced resistance to ionizing radiation in late S/G2 phase, which, in one case, correlates with an enhanced ability to rejoin dsbs. This, together with other evidence, suggests that two mechanisms of dsb rejoining may exist in higher eukaryotes, one which operates uniquely in S/G2 phase and a second mechanism operating throughout the cell cycle and dependent upon the xrs and XR-1 gene products (although whether the xrs and XR-1 dependent pathways are distinct cannot at present be ascertained). Since duplicate homologues will be present in late S/G2 phase cells, this pathway may involve a recombinational mechanism. The xrs-dependent pathway might involve illegitimate recombination, but the xrs mutants do not appear to have a major defect in homologous recombination (involving plasmid DNA) and in this respect are distinct from rad52 mutants.

Spontaneous CHO APRT heterozygotes reflect high-frequency, allele-specific deletion of the chromosome Z4 APRT gene

In Chinese hamster ovary (CHO) cells, heterozygotes for the adenine phosphoribosyltransferase (APRT) locus arise spontaneously at high frequencies. Paradoxically, such heterozygotes yield APRT mutants only at much lower spontaneous rates, suggesting that the high-frequency event may occur at only one of the two APRT genes. In an attempt to understand the genetic basis for the apparent refractivity of one of the APRT alleles to the high-frequency genetic event and to determine whether differences in the genomic environments of the two CHO APRT alleles specifically render one gene more susceptible to high-frequency spontaneous deletion or inactivation, we have mapped the wild-type APRT allele in 16 independently derived spontaneous APRT heterozygotes. In 15 of these 16 heterozygotes, the functional, wild-type APRT gene was found to reside on the Z7 chromosome, indicating that the high-frequency event is indeed highly specific for the Z4 APRT allele. All but one of these heterozygotes were hemizygous for the APRT locus, suggesting that the high-frequency event generally involves deletion rather than spontaneous inactivation or mutation of the Z4 APRT allele.

Properties and physiological function of the polyamine transport system

Polyamine transport was examined in Chinese hamster ovary (CHO) cells because of the unique potential these cells hold for utilizing genetic approaches to study the mechanisms of polyamine transport, its regulation, and its function. Parental (control) CHO cells were shown to contain a polyamine transport system with characteristics consistent with polyamine-uptake properties described in other cell types. Polyamines appear to cross the plasma membrane via an energy-requiring transport system specific for putrescine, spermidine, spermine, and their analogues. A mutant line, CHOMG, selected for resistance to the toxicity of methylglyoxal bis(guanylhydrazone), was shown to lack a functional polyamine transport system. CHOMG cells provided the negative controls necessary to examine the role of polyamine transport in maintenance of intracellular polyamine levels and in the regulation of the polyamine metabolic enzymes. It was found that the repression of ornithine decarboxylase activity by polyamines and the induction of spermidine/spermine-N1 acetyltransferase by polyamine analogues including bis(ethyl)spermine derivatives required the presence of a functional polyamine transport system. The CHO-CHOMG model was also shown to provide a means for establishing the importance of the polyamine transport system in the toxicity of polyamine analogues. The inability of alpha-difluoromethylornithine-treated CHOMG cells to utilize extracellular polyamines to replenish depleted intracellular polyamine levels suggested a means by which polyamine transport-positive cells may be identified. Such a selection procedure will permit the use of CHOMG cells in the isolation of genes encoding proteins involved in polyamine transport.

Preferential loss or inactivation of chromosome Z4 APRT allele in CHO cells

In CHO cells, heterozygotes for the adenine phosphoribosyltransferase (APRT) locus arise spontaneously at high frequencies. However, such heterozygotes always yield APRT- mutants at low spontaneous rates. In an attempt to determine whether differences in the genomic environments of the two CHO APRT alleles might render one gene more susceptible to high-frequency spontaneous inactivation or deletion, we have mapped the functional APRT allele in four different spontaneous APRT heterozygotes. In each case, the functional APRT gene was found to reside on the Z7 chromosome; it was always the Z4 APRT allele that had been lost or inactivated. Two of these heterozygotes were shown to be physically hemizygous while the other two retained two copies of the APRT gene, indicating that the high-frequency event can involve either spontaneous deletion or inactivation.

A genetic analysis of the adenine phosphoribosyl transferase locus in Chinese hamster V79-AP4 cells: relevance to mutagenesis studies

The chromosomal location of the autosomal locus aprt has been investigated in the permanent Chinese hamster cell line V79-AP4 by standard somatic cell genetics methodologies. Aprt is functionally dizygous in V79-AP4 and the 2 alleles map on 2 chromosome 3 homologs, in agreement with the chromosome assignment of the gene in Chinese hamster primary cells. Chromosome G-banding and a Southern blot analysis of V79-AP4 DNA, using as a probe the cloned Chinese hamster aprt gene, have not revealed any structural alteration at either of the 2 aprt alleles. One of the chromosomes 3 has, however, a terminal deletion in its long arm and is therefore morphologically marked. These findings could make V79-AP4 an interesting cell system for the study of mutational mechanisms at the aprt locus in Chinese hamster.

Methylglyoxal-bis(guanylhydrazone)-resistant Chinese hamster ovary cells: genetic evidence that more than a single locus controls uptake

Chinese hamster ovary cells spontaneously resistant to the cytotoxic action of methylglyoxal-bis(guanylhydrazone) have been isolated in a multistep selection scheme. A low-level resistant isolate has been shown to be defective in the ability to accumulate the drug intracellularly. This was reflected in a 10-fold lower Vmax than wild-type cells for drug uptake as well as a slight enhancement of drug efflux. More highly resistant isolates selected from this low-level resistant isolate were totally deficient in the ability to take up the drug. A partial revertant, selected from this low-level resistant isolate, retained some change in the Vmax for uptake but lost the accelerated rate of efflux characteristic of the low-level resistant line. Genetic analysis by somatic cell hybridization indicated that the low-level resistant phenotype was recessive to the wild-type phenotype. In addition, the low-level resistant phenotype could be complemented by a previously isolated highly resistant cell also defective in drug uptake (Mandel and Flintoff (1978) J. Cell. Physiol., 97: 335-344). Taken together, these data suggest that more than one locus controls drug uptake in Chinese hamster ovary cells.

Functional hemizygosity for the MDH2 locus in Chinese hamster ovary cells

Isolation of electrophoretic mobility shift mutants for a large number of enzyme loci in CHO cells has allowed the identification of many genes which are functionally hemizygous. To gain further insight into the nature of hemizygosity in CHO cells and the mechanisms by which it has arisen, we are attempting to determine whether hemizygous gene loci are clustered in a few localized chromosomal regions in CHO or are more generally distributed throughout the genome. Isozyme analysis of a series of CHO electrophoretic mobility shift mutants for MDH2 (malate dehydrogenase 2, EC 1.1.1.37) revealed that this locus is functionally hemizygous in CHO cells, but the locus could not be mapped by conventional approaches because of the similar electrophoretic mobilities of Chinese hamster and mouse MDH2 isozymes. Construction of intraspecific CHO X CHO hybrids using electrophoretic mobility shift mutants with secondary, selectable drug-resistance markers allowed us to determine that MDH2 is not closely linked to any previously mapped hemizygous marker loci in CHO, but is linked to alleles for two dizygous gene loci, PGM3 and APRT, on CHO chromosome Z7. A possible genetic basis for hemizygosity of the MDH2 locus in CHO cells is discussed.