Transfection of mouse cells with thymidine kinase gene of herpes simplex virus

A mouse cell line (LP1-1) was established from the murine L cells deficient in thymidine kinase (L-M(TK ^–)) by prolonged selective culture on the hypoxanthine-aminopterine-thymidine (HAT) medium following transfection with the thymidine kinase gene of herpes simplex virus type-I (HSVTK). Southern blot analysis has shown that the viral TK gene was integrated into one of the chromosomal loci by a single copy. From this established cell line, the 5-bromo-2-deoxyuridine (BrdU) resistant revertant was brought out at a frequency of 1×10^–6 and from these BrdU resistant revertants (LP1BU), one out of 1×10⁵ cells could return to the HAT-resistant phenotype. The established LP1-1 cell line showed a typical biphasic nature of DNA synthesis as determined by the ³H-thymidine incorporation test. The activity of thymidine kinase was shown to be equivalent to that of the DNA polymerase- when the whole nuclear fraction or the nuclear matrix were used for examination. These results indicate that the transfected viral TK gene can be expressed under the normal cell-cycle regulation and its gene product can act as a component of the multienzyme complex which is responsible for DNA replication.     

Identification of chick thymidine kinase determinant in somatic cell hybrids of chick erythrocytes and thymidine kinase-deficient mouse cells

Disc polyacrylamide gel electrophoresis (disc PAGE) analyses of chick-mouse somatic cell hybrids [LM(TK⁻)/CRB]isolated from fusion mixtures of chick erythrocytes and thymidine (TdR) kinase-deficient mouse [LM(TK⁻)]cells have demonstrated that the somatic cell hybrids contain only chick cytosol TdR kinase F and mouse mitochondrial TdR kinase A activities. Karyotypes were analysed by the method which sequentially reveals Q- and C-bands. Four hybrid clones contained the full complement of mouse chromosomes and 1 to 3 chick micro-chromosomes. Counterselection of the LM(TK⁻)/CRB hybrids in 5-bromodeoxyuridine (BUdR) medium resulted in the loss of chick cytosol TdR kinase F activity and at least one of the chick chromosomes, but mouse mitochondrial TdR kinase A activity was unaffected. Unlike the LM(TK⁻)/CRB somatic cell hybrids, the BUdR-resistant clones could not grow in HATG (hypoxanthine-aminopte-rin-thymidine-glycine) medium. The results demonstrate that: (1) the chick cytosol TdR kinase F gene is on a member of the micro-chromosomes; and (2) selection in HATG- and BUdR-containing medium involves only cytosol TdR kinase F.     

ACQUISITION OF CHICK CYTOSOL THYMIDINE KINASE ACTIVITY BY THYMIDINE KINASE-DEFICIENT MOUSE FIBROBLAST CELLS AFTER FUSION WITH CHICK ERYTHROCYTES

Chick-mouse heterokaryons were obtained by UV-Sendai virus-induced fusion of chick erythrocytes with thymidine (dT) kinase-deficient mouse fibroblast [LM(TK^-)] cells. Autoradiographic studies demonstrated that 1 day after fusion, [³H]dT was incorporated into both red blood cell and LM(TK^-) nuclei of 23% of the heterokaryons. Self-fused LM(TK^-) cells failed to incorporate [³H]dT into nuclear DNA. 15 clonal lines of chick-mouse somatic cell hybrids [LM(TK^-)/CRB] were isolated from the heterokaryons by cultivating them in selective hypoxanthine-aminopterin-thymidine-glycine medium. LM(TK^-) and chick erythrocytes exhibited little, if any, cytosol dT kinase activity. In contrast, all 15 LM(TK^-)/CRB lines contained levels of cytosol dT kinase activity comparable to that found in chick embryo cells. Disk polyacrylamide gel electrophoresis and isoelectric focusing analyses demonstrated that the LM(TK^-)/CRB cells contained chick cytosol, but not mouse cytosol dT kinase. The LM(TK^-)/CRB cells also contained mouse mitochondrial, but not chick mitochondrial dT kinase. Hence, the clonal lines were somatic cell hybrids and not LM(TK^-) cell revertants. The experiments demonstrate that chick erythrocyte cytosol dT kinase can be activated in heterokaryons and in hybrid cells, most likely as a result of functions supplied by mouse fibroblast cells.     

Evidence for chemically-induced structural gene mutations at the thymidine kinase locus in cultured L5178Y mouse lymphoma cells

L5178Y mouse lymphoma cells normally appear to possess two functional thymidine kinase alleles (TK^+/+). TK-deficient (TK^?/?) clonal lines can be derived from these cells by treatment with EMS or other mutagens. Mezger-Freed [12] has argued that such stable phenotypic variants do not arise as the result of gene mutations but instead represent epigenetic events such as normally occur during differentiation without any permanent gene alteration. If this be so, then rare TK^+/? revertants arising in TK^?/? cultures should possess TK enzyme identical with one of those present in the original TK^+/+ cells, since only depression of the TK gene is involved. Our studies show that this is not the case.Among the mutant TK enzymes analyzed in vitro (those from parental TK^+/? lines, each derived in turn from separate TK^?/? lines) differences were found in (1) solubility in saline; (2) solubility in3 M LiCl; (3) K_m′s; and (4) ATP-Mg²⁺ requirements. These findings were incompatible with a non-mutational model for the production of these stable variants and, in conjunction with reversion-rate data, they tended to favor either direct structural gene modifications or mutations affecting the expression of adult and fetal enzymes.     

Evidence for intrachromosomal gene conversion in cultured mouse cells

In this report we present an experimental scheme that facilitates the study of homologous recombination between closely linked genes in cultured mammalian cells. Two different Xho I linker insertion mutants of the herpes simplex virus type 1 thymidine kinase (HTK) gene were introduced into mouse LTK^? cells as direct repeats on a plasmid carrying a dominant selectable marker. Following stabilization of these sequences in the recipient cell, selection for TK⁺ was applied to detect recombinational events between different TK^? genes. TK⁺ segregants were observed at a frequency of 10^?4–10^?5 in lines harboring both mutant genes. Control lines carrying only one type of mutant HTK gene yielded TK⁺ cells at frequencies of 10^?7 or less. Physical analysis of the TK⁺ segregants has revealed the presence of an apparently normal HTK gene that is resistant to Xho I endonuclease digestion in each TK⁺ line examined. Analyses of the TK gene pairs before and after recombination suggest that at least 50% of the recombinants are the result of nonreciprocal exchanges of genetic information, or gene conversion events.     

Cotransfer of syntenic human genes into mouse cells using isolated metaphase chromosomes or cellular DNA

Summary Chromosome-mediated gene transfer (CMGT) of the human genes for hypoxanthine phosphoribosyl transferase (HPRT) and cytosol thymidine kinase (TK1) into HPRT deficient mouse A9 cells or TK deficient Swiss mouse 3T3TK^– cells was found to occur at frequencies at least one order of magnitude higher than DNA-mediated gene transfer (DMGT). The frequency of CMGT into 3T3TK^– cells was reduced by more than an order of magnitude by a posttreatment of the recipient cells with dimethyl sulphoxide (DMSO). After CMGT, expression of the non-selected genes coding for galactokinase (GALK) and acid alpha-glucosidase (GAA), both syntenic with TK1, was observed in a number of transformants. From the pattern of cotransfer, a tentative gene ordering of CENTROMERE-GALK-TK1-GAA on human chromosome 17 was deduced. Chromosome-mediated cotransfer of X-linked human phosphoglycerate kinase (PGK) with HPRT was observed in two out of 33 A9 transformants analysed. DNA-mediated cotransfer of a syntenic gene was only observed for GALK, cotransferred with TK1 in two out of 18 TK⁺ transformants of mouse LTK^– cells. Therefore, with murine cells as recipients of human donor genetic material, CMGT results in a higher frequency of transfer and a higher incidence of cotransfer of syntenic genes than DMGT using cellular DNA in the same cell system.     

Assignment of the gene for cystathionine β-synthase to human chromosome 21 in somatic cell hybrids

Summary Among several established mouse, rat, and Chinese hamster cell lines that were screened for cystathionine -synthase (CBS) activity, mouse 3T3 and Chinese hamster Don fibroblasts were found to contain no detectable activity. Somatic cell hybrids between human fibroblasts KG-7 with normal CBS activity and Don/a23TK^- cells (series XXI) were examined for CBS activity and for human chromosome content. Only chromosome 21 cosegregated with CBS activity. Because the activities measured could represent either Chinese hamster or human gene products, we have prepared a new series of hybrids between Don/a23TK^- cells and mutant human fibroblasts from a patient with homocystinuria due to deficiency of functional CBS mRNA. None of these (series XXV) hybrids contained detectable CBS activity, although collectively all human chromosomes were represented. Our results suggest that the human gene for CBS, called CBS, and thus for the most common form of homocystinuria, is located on chromosome 21.     

The human myoglobin gene: a third dispersed globin locus in the human genome.

Human myoglobin is specified by a single gene. Unique sequence DNA probes were isolated from the cloned gene and used to test for the presence of the human myoglobin gene in a series of human rodent somatic cell hybrids containing various complements of human chromosomes. The myoglobin gene cosegregated with human chromosome 22. Somatic cell hybrids containing translocation chromosomes carrying part of chromosome 22 were used to locate the myoglobin gene to the region 22q11----22q13. The myoglobin gene is therefore not linked to the alpha-globin gene cluster on chromosome 16 or the beta-globin cluster on chromosome 11, and represents a third dispersed globin locus in the human genome.     

Localisation of the human ABO: Np-1: AK-1 linkage group by regional assignment of AK-1 to 9q34

Summary Quantitative red cell adenylate kinase (AK-1) assay has been used in 8 patients with partial duplication or deletion of chromosome 9 in an attempt to find the precise intrachromosomal location of the structural gene locus. All regions of chromosome 9 are represented in abnormal dosage in at least one patient. A 43% increase in AK-1 activity was found to be associated with duplication of the terminal band of the long arm of chromosome 9. Duplication of all other parts of chromosome 9 were associated with normal enzyme activity. These findings not only confirm the assignment of the AK-1 locus to chromosome 9 made previously in somatic cell hybrids, but suggest a more precise assignment to region 9q33qter. This places the ABO: Np-1: AK-1 linkage group at the distal end of the long arm of chromosome 9.     

Human mitochondrial thymidine kinase is coded for by a gene on chromosome 16 of the nucleus

The expression of human mitochondrial thymidine kinase (mt TK) was investigated by polyacrylamide electrophoresis in 19 independent human-mouse somatic cell hybrids which allowed all human chromosomes to be analyzed. In 8 hybrid clones the presence of this enzymatic activity could be demonstrated. Human mt TK segregated concordantly with human adenine phosphoribosyltransferase (APRT) and human chromosome 16. Discordant segregation with all other human chromosomes was demonstrated by karyotype and isozyme analyses. These results suggest that human mt TK is coded for by a gene on chromosome 16 of the nucleus. Thus human mt TK is genetically different from human cytosol thymidine kinase which is coded for by a gene on chromosome 17. The appearance of one heteropolymer band after electrophoretic separation of human and murine mt TK supports the notion that both enzymes have dimeric structures.     

Contents Volume 93 (1982)

A thymidine kinase heterozygote was isolated from a diploid human lymphoblast line which forms colonies with high efficiency in microtiter dishes. We show that this cell line, called TK6, can be mutated from a tK^+/? to TK^?/? state by diverse mutagens, including ethyl methanesulfonate, butyl methanesulfonate, nitrosomethylurea, UV light, ICR-191, 4-nitroquinoline oxide, fluorodeoxyuridine, benzo[a]pyrene and aflatoxin B₁. We report here the experiments required to demonstrate the applicability of this new line in quantitative assays of mutation in human cells.Mitotic recombination between the centromere and the tk locus could not be induced by either dimethylsulfoxide or phorbol-12-myristate-13-acetate.     

Control of expression of the vaccinia virus thymidine kinase gene.

mRNA extracted from vaccinia virus-infected cells early after infection directs cell-free synthesis of enzymatically active viral thymidine kinase (Hruby and Ball, Virology, in press). We used this assay for a specific vaccinia virus mRNA to study the induction and repression of the viral thymidine kinase gene during infection of thymidine kinase-deficient L-cells. As observed previously by other workers, the synthesis of thymidine kinase occurred immediately after infection but was switched off after 4 h later. We observed similar kinetics of accumulation and shutoff under conditions where viral DNA synthesis and late gene expression were inhibited. Cell-free translation of mRNA from infected cells showed that the concentration of functional message for viral thymidine kinase reached a peak 3 to 4 h after infection and then decreased with a half-life of about 1 h. These kinetics indicated that significant levels of thymidine kinase mRNA persisted in cells which had stopped synthesizing the enzyme. Under conditions where late gene expression was inhibited, high concentrations of functional mRNA could be isolated from cells at late times after infection. On the basis of these results, we conclude that the repression of thymidine kinase expression is mediated at the translational level by one or more early or delayed early viral genes. Repression is accompanied by, but does not depend on, the inactivation or degradation of thymidine kinase mRNA, which is a late gene function.     

Targeting of interferon-beta to produce a specific, multi-mechanistic oncolytic vaccinia virus

Background

Oncolytic viruses hold much promise for clinical treatment of many cancers, but a lack of systemic delivery and insufficient tumor cell killing have limited their usefulness. We have previously demonstrated that vaccinia virus strains are capable of systemic delivery to tumors in mouse models, but infection of normal tissues remains an issue. We hypothesized that interferon-beta (IFN-β) expression from an oncolytic vaccinia strain incapable of responding to this cytokine would have dual benefits as a cancer therapeutic: increased anticancer effects and enhanced virus inactivation in normal tissues. We report the construction and preclinical testing of this virus.

Methods and Findings

In vitro screening of viral strains by cytotoxicity and replication assay was coupled to cellular characterization by phospho-flow cytometry in order to select a novel oncolytic vaccinia virus. This virus was then examined in vivo in mouse models by non-invasive imaging techniques. A vaccinia B18R deletion mutant was selected as the backbone for IFN-β expression, because the B18R gene product neutralizes secreted type-I IFNs. The oncolytic B18R deletion mutant demonstrated IFN-dependent cancer selectivity and efficacy in vitro, and tumor targeting and efficacy in mouse models in vivo. Both tumor cells and tumor-associated vascular endothelial cells were targeted. Complete tumor responses in preclinical models were accompanied by immune-mediated protection against tumor rechallenge. Cancer selectivity was also demonstrated in primary human tumor explant tissues and adjacent normal tissues. The IFN-β gene was then cloned into the thymidine kinase (TK) region of this virus to create JX-795 (TK⁻/B18R⁻/IFN-β⁺). JX-795 had superior tumor selectivity and systemic intravenous efficacy when compared with the TK⁻/B18R⁻ control or wild-type vaccinia in preclinical models.

Conclusions

By combining IFN-dependent cancer selectivity with IFN-β expression to optimize both anticancer effects and normal tissue antiviral effects, we were able to achieve, to our knowledge for the first time, tumor-specific replication, IFN-β gene expression, and efficacy following systemic delivery in preclinical models.     

The utilization of trifluorothymidine (TFT) to select for thymidine kinase-deficient (TK−/−) mutants from L5178Y/TK+/− mouse lymphoma cells

Trifluorothymidine (TFT), a thymidine analog, was analyzed for its ability to select for thymidine kinase-deficient (TK^−/−) mutants. In comparison with BUdR, the traditional selective agent for TK^−/− cells, it was determined that TFT at 1/50th the dose (1μg/ml vs. 50 μg/ml) is a more effective and versatile selective agent for TK^−/− mutants arising from the TK^+/−-3.7.2C heterozygote of L5178Y mouse lymphoma cells. Since TFT acts more rapidly than BUdR, it can be utilized in procedures (such as the analysis of the phenotypic lag) requiring the fast arrest of cell division. Reconstruction analyses of effective TK^−/− mutant recovery indicate that TFT can be used to recover mutants from significantly higher densities of TK^+/− cells than can BUdR. In addition, TK^−/− mutants can attain larger colony size in TFT than in BUdR where severe stunting of growth occurs at high TK^−/− cell densities. 190 of 194 isolated TFT-resistant large and small colony mutants (both spontaneous and induced)     

Alteration of human breast tumor cell membrane functions by chromosome-mediated gene transfer

BOT-2 cells (human breast tumor origin) have an impaired ability to utilize exogenous thymidine. Previous studies revealed this deficiency to be the permeation event rather than phosphorylation, since the cells have active thymidine kinase. Chromosome-mediated gene transfer was used to transfer genetic information in the form of metaphase chromosomes, from HeLa-65 cells to the BOT-2 cells, correcting the permease deficiency. Poly-L-ornithine or lipochromes were used for facilitation of chromosome uptake. After selection on HAT medium, transferant clones were isolated at a frequency of 4 X 10^?5 and 1 X 10^?5, respectively. Transferants MGP-1 and MGL-1 are stable after 18 months and have been characterized on the bases of purine and pyrimidine nucleoside uptake, relative thymidine kinase activities, alkaline phosphatase activities, and hydrocortisone-induced alkaline phosphatase activity. MGP-1 demonstrates positive thymidine uptake and incorporates radiolabeled thymidine into DNA. MGL-1 remains thymidine transport-deficient and survives on HAT by increasing endogenous dihydrofolate reductase activity. Alkaline phosphatase activity in MGL-1 is similar to HeLa-65, 2% of that in BOT-2, and in addition, is inducible 25-30-fold by 3 μM hydrocortisone. We have separated, genetically, a thymidine permease function from phosphorylation in cells of human origin and have transferred genetic information for the regulation of alkaline phosphatase.     

Expression of the ASV src gene in hybrids between normal and virally transformed cells: Specific suppression occurs in some hybrids but not others

Somatic cell hybrids have been made between clones of rat cells transformed by avian sarcoma virus and rat or mouse cells that are untransformed. Intraspecies hybrids were either predominantly morphologically normal or predominantly transformed, some clones that formed transformed intraspecies hybrids yielding normal interspecies hybrids. Untransformed hybrids usually showed no detectable alteration in the structure or location of the integrated provirus, but viral RNA and pp60^src kinase activities were much reduced. No decrease in viral gene expression was seen in transformed hybrids. Thus hybrid suppression of viral transformation, mediated in trans by the untransformed parent, is a specific event that depends on both untransformed and transformed parental parameters.     

Adenylate kinase 2, a mitochondrial enzyme

The subcellular compartmentalization of the isozymes of ATP: AMP phosphotransferase (adenylate kinase) was analyzed in HeLa cells, RAG cells, and RAG-human hybrids that express human AK-2. In HeLa cells and in the hybrids, human AK-2 was present in a mitochondrial fraction prepared from cell extracts and in mitochondria purified by density gradient centrifugation. Human AK-1 was, as expected, distributed in the soluble cytoplasmic fraction of the cells. The rodent isozymes which are homologous to human AK-1 and AK-2 have been determined.This work was supported by NIH Grants HD 04807-07 and HD 06285-04.     

SYNTHESIS OF UNNATURAL 7-SUBSTITUTED-1-(2-DEOXY-β-D-RIBOFURANOSYL)ISOCARBOSTYRILS†: “THYMINE REPLACEMENT” ANALOGS OF DEOXYTHYMIDINE FOR EVALUATION AS ANTIVIRAL AND ANTICANCER AGENTS

A group of unnatural 1-(2-deoxy-β-D-ribofuranosyl)isocarbostyrils having a variety of C-7 substituents [H, 4,7-(NO₂)₂, I, CF₃, CN, (E)-CH=CH-I, -C═CH, -C═C-I, -C═C-Br, -C═C-Me], designed as nucleoside mimics, were synthesized for evaluation as anticancer and antiviral agents. This class of compounds exhibited weak cytotoxicity in a MTT assay (CC₅₀=10^?3 to 10^?5 M range) with the 4,7-dinitro derivative being the most cytotoxic, relative to thymidine (CC₅₀=10^?3 to 10^?5 M range), against a variety of cancer cell lines. The 4,7-dinitro, 7-I and 7-C═CH compounds exhibited similar cytotoxicity against non-transfected (KBALB, 143B), and HSV-1 TK⁺ gene transfected (KBALB-STK, 143B-LTK) cancer cell lines possessing the herpes simplex virus type 1 (HSV-1) thymidine kinase gene (TK⁺). This observation indicates that these compounds are not substrates for HSV type-1 TK, and are therefore unlikely to be useful in gene therapy based on the HSV gene therapy paradigm.

     

Cytogenetic analysis of the L5178Y/TK+/− → TK−/− mouse lymphoma mutagenesis assay system

The L5178Y/TK^+/? → TK^?/? mouse lymphona mutagen assay, which allows selection of forward mutations at the autosomal thymidine kinase (TK) locus, uses a TK^+/? heterozygous cell line, TK^+/? 3.7.2C. Quantitation of colonies of mutant TK^?/? cells in the assay forms the basis for calculations of mutagenic potential of test compounds. We have evaluated the banded karyotypes of the parent TK^+/? heterozygous cell line, as well as homozygous TK^?/? mutants, in order to relate the genetic and morphological properties of mutant colonies. The parent cell line displays karyotype homogeneity, all cells containing normal mouse chromosomes, readily identifiable chromosome rearrangements, and cell line specific marker chromosomes. Mutant TK^?/? colonies of the TK^+/? 3.7.2C cell line form a bimodal frequency distribution of colony sizes for most mutagenic or carcinogenic test substances. Large-colony (λ) TK^?/? mutants with normal growth kinetics appear karyotypically identical within and among clones and with the TK^+/? parental cell line. In contrast, most slow-growing small-colony (σ) TK^?/? mutants have readily recognizable chromosome rearrangements involving chromosome 11, which contains the thymidine kinase gene locus. It is possible that the heritable differences in growth kinetics and resultant colony morphology in λ and σ mutants are related to the type of chromosomal damage sustained. Large-colony mutants receive minimal damage, possibly in the form of point mutations at the TK locus, while small-colony mutants receive damage to other genetic functions coordinately with loss of TK activity, implying gross insult to chromosomal material. It seems likely that λ and σ mutants result from 2 different mutational mechanisms that may be distinguished on the basis of mutant colony morphology.     

Analysis of the Relationship between Cellular Thymidine Kinase Activity and Virulence of Thymidine Kinase-Negative Herpes Simplex Virus Types 1 and 2

The virulence of thymidine kinase-negative herpes simplex virus type 1 (HSV-1; VRTK^? strain) and type 2 (HSV-2; UWTK^? strain) was studied in comparison with that of their parental strains (VR-3 and UW-268, respectively) in an encephalitis model of adult (4-week-old) and newborn (3-day-old) mice. Viral thymidine kinase (TK) activity was essential for the maximum expression of virulence of HSV-1, because the 50% lethal dose (LD₅₀) of VRTK^? was 60 times higher than that of VR-3 in the brains of newborn mice expressing high levels of cellular TK activity. However, the UWTK^? strain showed the same virulence as the parental strain in newborn mice, despite the lack virulence in adults, suggesting that replication of the UWTK^? strain was completely supported by cellular TK activity. This difference in the role of viral and cellular TKs for virus growth between HSV-1 and HSV-2 was confirmed with the one-step growth of virus strains in L-M and L-M(TK^?) cells.