Complementation of multiple sulfatase deficiency in somatic cell hybrids

Multiple sulfatase deficiency (MSD) is an inherited disorder characterized by deficient activity of seven different sulfatases. Genetic complementation for steroid sulfatase (STS), arylsulfatase A, and N-acetylgalactosamine 6-SO4 sulfatase was demonstrated in somatic cell hybrids between MSD fibroblasts and mouse cells ( LA9 ) or Chinese hamster cells ( CHW ). In an electrophoretic system that separates human and rodent STS isozymes, enzyme from hybrids migrated as human enzyme. We concluded that the rodent cell complemented the MSD deficiency and allowed normal expression of the STS structural gene. Some MSD- LA9 hybrids showed significant levels of human arylsulfatase A activity, as shown by the immunoprecipitation of active enzyme by human-specific antiserum. Complementation was also suggested for N-acetylgalactosamine 6- sulfatate sulfatase (GalNAc-6S sulfatase) in several MSD- LA9 hybrids by the demonstration of a significant increase in activity (10-fold) over that of the GalNAc-6S sulfatase-deficient parental mouse and MSD cells. Thus, it was possible to demonstrate complementation for more than one sulfatase in a single MSD-rodent hybrid. Normal levels of sulfatase activity in hybrids indicate that the sulfatase structural genes are intact in MSD cells.     

Characterization of hypoxanthine-guanine phosphoribosyl transferase in man-mouse somatic cell hybrids by an improved electrophoretic method

The hypoxanthine-guanine phosphoribosyl transferase (HGPRT) activity in a group of man-mouse somatic cell hybrids, produced by Sendai virus-mediated cell fusion and HAT selection, has been analyzed by a new electrophoretic technique. Evidence is presented which shows that the hybrid lines derived from fusion of a mouse fibroblast deficient in HGPRT with various human cell strains have an HGPRT activity that is characteristic of the human enzyme, whereas a hybrid line derived from a mouse fibroblast which is deficient in thymidine kinase has an HGPRT activity characteristic of the mouse. This new technique involves electrophoresis of cell extracts on cellulose acetate gel, followed by the localization of the enzyme activity by autoradiography.This research was supported in part by a research grant from the U.S. National Institutes of Health (No. GM-13415).     

Expression and properties of acetylcholine receptors in several clones of mouse neuroblastoma X L cell somatic hybrids

Three clones of somatic cell hybrids between neuroblastoma and L cells, NL-1F, NL-308 and NL-309 (3), have been studied for their electrical excitability and chemosensitivity to acetylcholine (Ach) applied by iontophoresis. Parental and hybrid lines were all treated and tested in media containing mM db-cAMP. The percentage of excitable N X L hybrid cells was as high or higher than that of their neuroblastoma parents. The percentage of cells sensitive to Ach was several-fold higher for the three N X L clones than for the neuroblastoma or L cell parents. While the neuroblastoma parents gave only depolarizing cholinergic responses, the N X L hybrid cells displayed slow hyperpolarizing (H) responses which resembled the H-cholinergic response obtained from L cells. The H-response of the N X L hybrids has properties which indicate the involvement of a muscarinic receptor. A correlation between expression of muscarinic receptors and excitability to electrical current (i.e., action potential ionophores), not found in the neuroblastoma parents, was present in the hybrids. However, a few N X L hybrid cells expressed muscarinic receptors independently from electrical excitability, as is the case for the L cell parent. The three N X L clones are discussed as potentially useful models to study interaction of Ach with muscarinic receptors.     

Electrical excitability and chemosensitivity of mouse neuroblastoma X mouse or human fibroblast hybrids

Intracellular microelectrode recording techniques were used to measure passive membrane properties, electrical excitability and chemosensitivity of mouse neuroblastoma cells and somatic cell hybrids formed between these cells and either L cells or human diploid fibroblasts. Different clones of the hybrid cells showed varying degrees of neuronal or fibroblastic membrane-differentiated function; a selection technique involving incubation of the cells with aminopterin gave quite homogeneous non-dividing populations of cells within a given clone of the neuroblastoma x L cell hybrids. Despite relatively uniform chromosomal numbers within a given clone, the neuroblastoma x human fibroblast hybrids were morphologically and electrophysiologically heterogeneous. The possibility is considered that this may represent the effect of variable segregation of the human chromosomal complement.     

Expression of nervous system antigen-3 by lines of mouse fibroblasts and kidney cells and continued expression in hybrid cells

In a survey of the expression on cultured mouse cells of the cell surface antigen known as nervous system antigen-3 (NS-3), it was found that RAG, a renal adenocarcinoma line, expressed that antigen. It was also observed that 3T3, a fibroblast line of unknown tissue origin, expressed NS-3. Cells of these two lines were hybridized with cells of two mouse L cell lines that did not express NS-3. Four hybrid clones were tested for both the 3T3 × L cell cross and the RAG × L cell cross, and all the hybrids were found to be NS-3 positive. All the hybrids had at least 40% as much activity as the NS-3 positive parent. Of the four parental mouse cell lines used, only 3T3 expressed Thy-1.2 antigen on the cell surface. In contrast to the continued expression of NS-3 on hybrid cells, Thy-1.2 antigen was not detectable on two clones of 3T3 × L cell hybrids that were tested.     

Assignment of the gene for acid beta-glucosidase to human chromosome 1.

The structural gene for human acid beta-glucosidase (GBA) has been assigned to chromosome 1 using somatic cell hybridization techniques for gene mapping. The human enzyme was detected in mouse RAG cell-human fibroblast cell hybrids by a sensitive double antibody immunoprecipitation assay using a mouse antihuman GBA antibody. No cross-reactivity between mouse beta-glucosidase and human GBA or neutral beta-glucosidase (GBN) was observed. Fifty-two primary, secondary, and tertiary manmouse hybrid lines, derived from three separate fusion experiments, were analyzed for human GBA and enzyme markers for the human chromosomes. Without exception, the presence of human GBA in these hybrid clones was correlated with the presence of human chromosome 1 or its enzymatic markers, phosphoglucomutase 1 (PGM1), and fumarate hydratase (FH). All other human chromosomes were eliminated by the independent segregation of GBA and their respective enzyme markers and/or chromosomes. Using a RAG X human fibroblast line with a mouse-human rearrangement of human chromosome 1, the locus for GBA was limited to the region 1p11 to 1qter.     

Membrane excitability expressed in human neuroblastoma cell hybrids

The voltage-sensitive Na+ channel is responsible for the action potential of membrane electrical excitability in neuronal tissue. Three methods were used to demonstrate the presence of neurotoxin-responsive Na+ channels in two hybrid cell lines resulting from the fusion of excitable human neuroblastoma cells with mouse fibroblasts. Only one of the two electrically active hybrid cell lines maintained the sensitivity of the neuroblastoma parent to tetrodotoxin (TTX). The other hybrid, although electrically active, was not responsive to TTX or scorpion venom. Comparisons of the patterns of expression of membrane excitability and of chromosome complements in these human neuroblastoma cell hybrids suggest that the phenotype of membrane excitability is composed of genetically distinct elements.     

Genetic linkage studies of the human glycosphingolipid β-galactosidases

The genetic linkage relationships of the human glycosphingolipid beta-galactosidases were determined using human--mouse somatic cell hybrids. A new method was devised for the estimation of human galactosylceramide, lactosylceramide, and GMI-ganglioside beta-galactosidase activities in the presence of their mouse counterparts, which takes advantage of the reproducible specific activity of lysosomal hydrolases under a given set of culture conditions and is based on differences in both pH optima and sensitivity to chloride ion. Human and mouse chromosomes were identified by their characteristic banding patterns obtained after quinacrine staining, and the optimum glycolipid beta-galactosidase activity was determined for three different substrates. A ratio was defined for each activity which was the specific activity at the human pH optimum divided by the specific activity at the mouse pH optimum. Linear regression analysis was used to test for concordant segregation between pH ratios for each enzyme and the frequency of occurrence of different human chromosomes in the man--mouse somatic hybrid clones. The results obtained from two independent series of hybrid clones indicated that human beta-galactosidase activities consistently segregated with human chromosome 12 in these somatic cell hybrids.     

Synthesis of isoflavene-thiosemicarbazone hybrids and evaluation of their anti-tumor activity

Phenoxodiol is an isoflavene with potent anti-tumor activity. In this study, a series of novel mono- and di-substituted phenoxodiol-thiosemicarbazone hybrids were synthesized via the condensation reaction between phenoxodiol with thiosemicarbazides. The in vitro anti-proliferative activities of the hybrids were evaluated against the neuroblastoma SKN-BE(2)C, the triple negative breast cancer MDA-MB-231, and the glioblastoma U87 cancer cell lines. The mono-substituted hybrids exhibited potent anti-proliferative activity against all three cancer cell lines, while the di-substituted hybrids were less active. Selected mono-substituted hybrids were further investigated for their cytotoxicity against normal MRC-5 human lung fibroblast cells, which identified two hybrids with superior selectivity for cancer cells over normal cells as compared to phenoxodiol. This suggests that mono-substituted phenoxodiol-thiosemicarbazone hybrids have promising potential for further development as anti-cancer agents.     

Genetic Dissection of Neural Properties using Somatic Cell Hybrids

A set of neuronal genes can be expressed in neuroblastoma × L cell hybrids and hybrid cell lines with specific defects in neural function can be generated in high yield.     

Extinction of globin gene expression in human fibroblast x mouse erythroleukemia cell hybrids.

We have chosen human fibroblast x mouse erythroleukemia hybrid cells as a model system to examine regulation of unique genes. The globin genes were studied as a marker of erythroid differentiation. Three separate hybrid cell lines were incubated in 2% dimethylsulfoxide, an agent which induces erythroid differentiation of the parental erythroleukemia cells. Neither human nor mouse globin mRNA sequences could be detected by a sensitive molecular hybridization assay which utilized globin complementary D N A. However, td n a from one of the cell lines was shown to contain both the mouse and humand globin genes. Thus, loss of the genes by chromosomal segregation did not account for their failure to be expressed. Cocultivation of the mouse erythroleukemia cells with excess human fibroblasts did not prevent erythroid differentiation of the erythroleukemia cells in the presence of dimethylsulfoxide. Similarly globin gene expression was preserved in tetraploid cells generated by fusion of two erythroleukemia lines. Thus, extinction of globin geneated by fusion of two erythroleukemia lines. Thus, extinction of blobin gene expression in the human fibroblast x erythroleukemia hybrids occurred at the level of mRNA production and appeared to be due to the presence of the fibroblast genome within the hybrial cell.     

Histone gene expression and chromatin structure in mammalian cell hybrids

DNA isolated from mammalian cell nuclear reveals discrete size patterns when partially digested with micrococcal nuclease. The DNA repeat lengths from different tissues within a species or from different species may vary. These differences have been attributed to the presence of different species of histone H1. To examine the nature of regulation of DNA repeat lengths and their possible relationship to histone H1, we have selected several mouse and human cell lines that differ in their DNA repeat lengths and examined them and their cell hybrids. 24 mouse X human and five mouse X mouse hybrid cell lines were analyzed. All the interspecific hybrids exhibited the repeat pattern characteristic of the murine parent. The mouse intraspecific hybrids had a repeat pattern of only one of the parents. We conclude that the partial human chromosome complements retained in the hybrids assume the repeat lengths exhibited by the mouse cells. Because H1 histones have been implicated in the determination of DNA repeat lengths, we also investigated the regulation of H1 histone expression in these cell hybrids. Purified H1 histones were radioactively labeled in vitro, and individual subfractions were subjected to proteolysis followed by gel electrophoresis. The resulting partial peptide maps off H1 histone subfractions A and B were distinguishable from one another and from different cell lines. In the mouse X human hybrids analyzed, only the mouse H1 histones were detected. These observations were extended to H2b by analysis of the hybrid cell histone by Triton-acid-urea gels. Neither the DNA repeat length nor histone expression is affected by the presence of any specific human chromosome. The fact that human genes are expressed in these hybrids suggests that the H1 histones of one species is able to interact with the chromatin of another species in a biologically funtional conformation. Analysis of the intraspecific PG19 X B82 (mouse X mouse) hybrids reveals the presence of H1 histone subfractions of the B82 mouse cells. Because these hybrids exhibit the nucleosome repeat length only of the PG19 cells, it appears that if histone H1 plays a role in determining the repeat length it does so in consort with other nonhistone chromosomal proteins.     

Characteristics of somatic cell hybrids (mouse x Chinese hamster) with a different ratio of chromosome sets from the parent species. II. Thymidine kinase activity]

The activity of thymidine kinase (TK) was studied in series of somatic cell hybrids between the mouse cell line 3T3-4E (TK-) and Chinese hamster cells M-15-1 (HGPRT-). Four groups of hybrid lines with different ratio of parental chromosome sets have been investigated: 1) three lines containing one hamster and one mouse chromosome set (1 hs+1 ms); 2) one line with 2 hs+1 ms; 3) one line containing 3 hs+1 ms and 4) one line containing 1 hs+2 ms. Mixtures of extracts from the parental cells were shown to possess the expected TK activity. The calculation of the activity per cell revealed that the 1 hs+1 ms and 2 hs+1 ms hybrid lines possessed about 50% of the initial hamster cell TK activity. The decreased TK activity in these hybrids might be due either to a loss of hamster chromosomes or to some inhibitory effect of mouse genome in cells with the studied ratio of parental sets. The enzyme activity in the 3 hs+1 ms hybrid was as expected, about three times greater than that of hamster cells.     

Presence of human chromosome 21 alone is sufficient for hybrid cell sensitivity to human interferon.

Human/mouse somatic cell hybrids with chromosome 21 as the only detectable human genetic material were sensitive to both human leukocyte and fibroblast interferons. The presence of additional human chromosomes decreased the amount of interferon needed to attain a given level of virus resistance. Decreased cytopathic effects, decreased virus yields, and the appearance of a specific phosphorylated protein associated with interferon treatment were all observed in hybrids maintaining only human chromosome 21. The phosphorylated protein found in extracts of these human interferon-treated hybrid cells was of mouse origin.     

Genetic control of tumorigenicity in interspecific mammalian cell hybrids.

The nature of genetic control of cellular malignancy was investigated by examining the tumorigenicity of a series of interspecific mouse-human cell hybrids in the athymic nude mouse. Two highly malignant but genetically distinct mouse cell lines, A9 and PG19, were hybridized with three normal human diploid fibroblast strains, and 19 independently arising hybrid clones were isolated. Each of these clones was capable of forming progressive lethal tumors in the nude mouse, and thus resembled the malignant parental mouse cells rather than the nonmalignant parental human cells. We failed to obtain any evidence for complete suppression of tumorigenicity in these cell hybrids. The absence of suppression was observed regardless of the extent and composition of the human chromosome complements retained in the hybrid clones; the results of detailed cytological and isoenzyme analyses would make it highly improbable that the observed lack of suppression was due to cellular selection in vivo for a more tumorigenic subpopulation in the injected hybrid cells. These data demonstrate that at least for the parental cell combinations used in this study, no human chromosome, when present singly in the mouse-human cell hybrids, can suppress the tumorigenic phenotype of the mouse cells. Our results are consistent with the view that the suppression of cellular malignancy previously demonstrated in intraspecific (mouse × mouse) somatic cell hybrids does not occur in interspecific (mouse-human) cell hybrids, or alternatively, genetic determinants located on two or more human chromosomes are required simultaneously to suppress the malignancy of the mouse cells in cell hybrids derived from malignant mouse cell and nonmalignant human cells.     

DIFFERENTIATION OF NEUROBLASTOMA, GLIOMA, AND HYBRID CELLS IN CULTURE AS MEASURED BY THE SYNTHESIS OF SPECIFIC PROTEIN SPECIES: EVIDENCE FOR NEUROBLAST-GLIOBLAST RECIPROCAL GENETIC REGULATION

Abstract— Protein species from differentiating neuroblastoma, glioma, and hybrid neuroblastoma-glioma cell lines in cell culture were separated and identified initially in the first dimension by the use of isoelectric focusing gels and were further separated in the second dimension by SDS-acrylamide gels. There were two main classes of proteins identified: proteins which were dominantly expressed in neuroblastoma and also in hybrid cell cultures, and proteins which were expressed in glioma and also hybrid cell cultures. In general, proteins were identified which were significantly expressed in neuroblastoma cells and much reduced in glioma cultures, and also conversely so. The hybrid cell line expressed many of the neuroblastoma-type proteins and relatively fewer of the glioma type proteins. A specific protein species (2) was identified in hybrid cells and was not present in either parental neuroblastoma or glioma cultures. Protein z was expressed however by the co-culturing of neuroblastoma and glioma cells suggesting its induction is dependent on a soluble factor. Protein z in hybrid cells was demonstrated in both stained gels and by autoradiography. Chromosome analysis of hybrid cells confirmed the presence of both rat and mouse chromosomes. It is suggested that similar neuronal-glial interaction may be functional in the intact brain, and that similar reciprocal modulation between neurons and glia may be a central mechanism of differentiation in the nervous system.     

Enhanced expression of alkaline phosphatase in hybrids between neuroblastoma and embryonal carcinoma

Three independent hybrid cell lines were isolated from the fusion of clonal lines of embryonal carcinoma and neuroblastoma. A series of subclones was subsequently derived from the original hybrid clones. In early hybrid generations all hybrid lines showed enhancement of alkaline phosphatase activity, expressing 2--8 times the activity of the teratoma parental line. The overexpression of APase appears to take place in the stationary phase of the growth cycle. Segregation for very high levels of APase activity was observed among subclones of one hybrid line. Specific activities of the segregants ranged from 0.1 to 133. Results of heat denaturation studies are consistent with the hypothesis that it is the embryonal carcinoma APase that is being expressed in the hybrids.     

Microsomal epoxide hydrolase activity in human x mouse hybrid cells

Microsomal epoxide hydrolase (E.C.3.3.2.3) activity has been measured in human x mouse hybrid cells prepared from human cells expressing 6-7 x the activity of the mouse cells. Rabbit antihuman and antimouse antisera raised against purified enzymes were used to discriminate between human and mouse enzymes. All twenty five clones examined did not express human enzyme and this correlated with the loss of human chromosome 6 from each cell line. Four hybrids expressed 2-3 x the activity expressed by the mouse cell parent and these all retained more human chromosomes, specifically chromosome 19, than those with low activity. It is concluded that the human gene for epoxide hydrolase may be on chromosome 6 and that other gene products can affect the level of activity expressed by a cell.     

Supermelanotic hybrids derived from mouse melanomas and normal mouse cells

Hybrids formed between HPRT- Cloudman mouse melanoma and normal cells were isolated. The parental origin of the hybrids was verified by isoenzyme and karyotype analyses. These hybrid cells differed in two major characteristics from hybrids of melanoma and established fibroblastic cells. (1) They grew as tumors when injected into mice, and (2) they expressed differentiated melanocytic functions. At least one of the differentiated functions was overexpressed. The specific activity of tyrosinase was 3-20 times higher in the hybrid cells than in the parental mouse melanoma. The overexpression of tyrosinase in these hybrid cells has been stable for more than a year, has been transmitted to subclones of the original hybrid cell lines, and has been expressed in tumors that grew after injections of hybrid cells into animals.     

Expression of a specific neuronal protein, 14-3-2, during in vitro differentiation of neuroblastoma cells

Expression of the neuronal marker 14-3-2 or NSE (neuron-specific enolase) has been studied during in vitro differentiation of cells in culture. The 14-3-2 protein of neuroblastoma cells is immunologically identical with that found in mouse brain extract. The lack of detectable 14-3-2 in cultures of non-neuronal lines shows that this protein, as has been already shown in vivo, is also a specific marker of neurons in vitro. The presence of 14-3-2 in a differentiated hypothalamic clone—but not in its presumptive precursor—indicates selective initial derepression of 14-3-2. Moreover, modulation of the amount of 14-3-2 already present in dividing neuroblastoma cells is related to the confluent phase of growth or morphological differentiation of neuroblasts. Both mechanisms may be related to the mechanisms underlying initial differentiation and subsequent maturation of neurons in vivo. In dividing neuroblastoma cells modulation of the basal level of 14-3-2 is not necessarily associated with expression of the morphological differentiation, but seems generally concomitant with an arrest of cell division.