Thomas J. Moehring

Characterization of the diphtheria toxin-resistance system in Chinese hamster ovary cells

Variations in two general classes of diphtheria toxin-resistant mutants which may be selected from Chinese hamster ovary (CH0-K1) cells and the conditions for their selection are described. The resistance of class I mutants can be overcome with increasing concentrations of toxin. Their entire complement of EF-2 is susceptible to ADP-ribosylation by toxin. Class I includes those strains in which resistance resides at the level of the plasma membrane. The resistance of class II, translational, mutants cannot be overcome by high concentrations of toxin, as all, or a portion, of their EF-2 is insensitive to the action of diphtheria toxin and Pseudomonas exotoxin A. Adjustment of the concentration of toxin used to select resistant mutants can be used to regulate the class of mutant recovered. Metabolic cooperation between cells does not affect recovery of either class I or class II mutants. Resistance is stable in class I strains, but class IIb strains, which possess 50 % resistant and 50 % sensitive EF-2, display a transient high level of resistance which is retained for varying lengths of time following exposure to toxin. Class IIa strains, which possess 100% resistant EF-2, grow normally in saturating concentrations of toxin, but class IIb strains grow at a reduced rate. Evidence is presented which suggests that the gene for EF-2 is functionally diploid in CH0-K1 cells.

Endoprotease Activities Other Than Furin and PACE4 with a Role in Processing of HIV-I gp160 Glycoproteins in CHO-K1 Cells

We addressed the question of whether furin is the endoprotease primarily responsible for processing the human immunodeficiency virus type I (HIV-I) envelope protein gp160 in mammalian cells. The furin-deficient Chinese hamster ovary (CHO)-K1 strain RPE.40 processed gp160 as efficiently as wild-type CHO-K1 cells in vivo. Although furin can process gp160 in vitro, this processing is probably not physiologically relevent, because it occurs with very low efficiency. PACE4, a furin homologue, allowed processing of gp160 when both were expressed in RPE.40 cells. Further, PACE4 participated in the activation of a calcium-independent protease activity in RPE.40 cells, which efficiently processed the gp160 precursor in vitro. This calcium-independent protease activity was not found in another furin-deficient cell strain, 7.P15, selected from the monkey kidney cell line COS-7.

Analysis of mutations in alleles of thefur gene from an endoprotease-deficient chinese hamster ovary cell strain

RPE. 40 mutant cells differ from wild-type Chinese hamster ovary (CHO-K1) cells in their increased resistance toPseudomonas exotoxin A and their inability to process the insulin proreceptor and certain viral envelope proproteins. Northern analysis revealed that RPE. 40 cells maintained a substantially lower steady-state level of 4.0 kbfur mRNA than did CHO-K1 cells. Analysis offur cDNAs showed that RPE. 40 cells were diploid at thefur locus, and RPE. 40 cells had a Cys (TGC) to Tyr (TAC) mutation in codon 196 of one allele (allele I). Approximately 25–30% of the CHO-K1 cells were also heterozygous (Tyr/Cys) at codon 196, and pre-mRNAs transcribed from the second allele (allele II) in RPE. 40 cells were defectively spliced. All other pre-mRNAs were correctly spliced. Rapid turnover of defectively spliced transcripts may account for the reduced steady-state level offur mRNA observed in RPE. 40 cells. Our results provide a mechanistic basis for the endoprotease-deficient phenotype of RPE. 40 cells.

A mutation in codon 717 of the CHO-K1 elongation factor 2 gene prevents the first step in the biosynthesis of diphthamide

The histidine residue at position 715 of elongation factor 2 (EF-2) is posttranslationally modified in a series of enzymatic reactions to 2-[3-carboxyamido-3-(trimethylammonio)-propyl]histidine, which has been given the trivial name diphthamide. The diphthamide residue of EF-2 is the target site for ADP ribosylation by diphtheria toxin and Pseudomonas exotoxin A. ADP-ribosylated EF-2 does not function in protein synthesis. EF-2 that has not been posttranslationally modified at histidine 715 is resistant to ADP ribosylation by these toxins. In this report we show that a G-to-A transition in the first position of codon 717 of the EF-2 gene results in substitution of arginine for glycine and prevents addition of the side chain of diphthamide to histidine 715 of EF-2. EF-2 produced by the mutant gene is fully functional in protein synthesis.

Codominant translational mutants of Chinese hamster ovary cells selected with diphtheria toxin.

Diphtheria toxin-resistance markers in two translational mutants, CH-RE1.22c, possessing no toxin-sensitive EF-2 (class IIa), and CH-RE1.32, with 50% toxin-sensitive and 50% toxin-resistant EF-2 (class IIb), behaved codominantly in somatic cell hybrids. There was no complementation in hybrids formed between the two resistant mutants. The mutant parents and their hybrids, except those formed by fusion of CH-RE1.32 and wild-type cells, grew in the presence of toxin. To explain these results we suggest that CHO-K1 cells possess two functional copies of the gene for EF-2 and that CH-RE1.22c and CH-RE1.32 represent the homozygous (R/R) and heterozygous (R/S) states of resistance at the EF-2 gene locus. The failure of hybrids formed between CH-RE1.32 and wild-type cells to grow in toxin is a gene dosage effect. Codominant class IIa translational resistance is a selectable marker for the isolation of hybrids. It can be combined with a second, recessive, marker to provide a cell which is a “universal hybridizer” (10).

Enzyme treatment of KB cells: The altered effect of diphtheria toxin

Abstract Treatment of KB cells with trypsin, phospholipase C and pronase at concentrations which did not affect viability or rate of incorporation of amino acids into protein lowered significantly the inhibition of protein synthesis by diphtheria toxin. Chymotrypsin was effective but only at concentrations toxic to the cells. Lipase and neuraminidase had no effect. It is evident that enzyme-sensitive cell surface components with specificity for diphtheria toxin are present on the KB cell.

Lymphotoxin Production in Human Neoplasia

Summary The in vitro release of lymphotoxin by human peripheral blood lymphocytes from noncancer patients, patients with cancer, and patients with Hodgkins disease were studied. Noncancer patients and patients with cancer other than Hodgkins disease released no lymphotoxin under unstimulated conditions while stimulation with phytohemagglutinin induced in vitro release of lymphotoxin. Lymphocytes from patients with Hodgkins disease released significantly less lymphotoxin following stimulation with phytohemagglutinin but also released measurable amounts of a lymphotoxin-like substance in the unstimulated state. Hodgkins disease lymphocytes appear to differ from the lymphocytes of noncancer patients and patients with cancer other than Hodgkins disease by both lower in vitro lymphotoxin release following phytohemagglutinin stimulation and spontaneous release of lymphotoxin by unstimulated lymphocytes.

Structural and Functional Analysis of the Protein Products Derived From Mutant fur Alleles in an Endoprotease-Deficient Chinese Hamster Ovary Cell Strain

The fur gene encodes the endoprotease, furin. We recently demonstrated mutations in both fur alleles in the mutant Chinese hamster ovary (CHO)-K1 strain, RPE.40, and hypothesized that these mutations were responsible for the endoprotease-deficient phenotype of these cells. We now present the structural and functional properties of three protein products derived from the mutant fur alleles. None of these protein products were able to process the precursor to von Willebrand factor, which is processed by wild-type furin. Pro-protein processing activity initially attributed to one of the mutant proteins was due to wild-type furin produced inadvertently from one of the expression constructs used in these experiments. None of the mutant proteins exhibited evidence of autocatalysis, consistent with the lack of activity versus the test substrate, and glycosylation patterns suggested at least two of them remained in the endoplasmic reticulum. These results confirm that RPE.40 cells are furin null mutants, as earlier evidence had suggested.