Outcome of conservative therapy for invasive breast cancer by histologic subtype

Between 1977 and 1986, 879 patients with Stage I and II breast cancer underwent excisional biopsy, axillary dissection, and radiation. Median follow-up was 61 months (range 2-159 months). The patients were divided into seven groups based on histologic subtype: (a) 368 patients with both infiltrating and intraductal ductal carcinoma, (b) 389 infiltrating ductal carcinoma, (c) 41 infiltrating lobular carcinoma, (d) 23 combined infiltrating ductal and lobular carcinoma, (e) 28 medullary carcinoma, (f) 12 colloid carcinomas, and (g) 18 tubular carcinomas. Significant differences in clinical T status, pathologic nodal involvement, administration of chemotherapy, estrogen receptor positivity, progesterone receptor positivity, and age were observed between some histologic subgroups. Tubular and colloid carcinomas were more likely to present with T1 lesions, hormone receptor positivity, and node negative status than the other histologic subtypes. Most medullary carcinomas were hormone receptor negative and were younger than 50 years old. Infiltrating lobular carcinoma patients were more frequently lymph node negative, older, node negative, and estrogen receptor positive compared to the other groups (except for tubular and colloid patients). Differences in the administration of chemotherapy primarily reflected differences in lymph node involvement. Location of the tumor in the breast and menopausal status did not correlate with histologic subtype. There were no significant differences in 5-year actuarial overall survival, cause-specific survival, or relapse-free survival between the histologic categories. In addition, patterns of first failure were not significantly different among the histologic groups in terms of local-only first failure, any local component of first failure, regional-only first failure, or any regional component of first failure. There was, however, a difference among the seven groups in distant metastasis-only at first failure with invasive ductal carcinomas having the highest rate. Despite this difference, histologic subtype had no impact on survival. The site of in-breast failure relative to the location of the original tumor was not significantly different between groups. The histologic subtype of invasive breast cancer is not an independent risk factor in predicting survival or pattern of failure. Conservative surgery and radiation therapy is effective treatment of ductal, lobular, medullary, colloid, and tubular invasive breast cancer.

Increased G2 delay in radiation-resistant cells obtained by transformation of primary rat embryo cells with the oncogenes H-ras and v-myc

Cell cycle perturbation after irradiation was studied in five cell lines transfected with oncogenes. Two immortalized, radio-sensitive cell lines with D0s of 1.06 and 1.08 Gy were compared to three radioresistant cell lines with D0s of 1.68-2.17 Gy. The sensitive cell lines were transfected with the v-myc or c-myc oncogenes, the resistant cell lines with the v-myc plus H-ras oncogenes. Exponentially growing populations were exposed to 5, 10, or 15 Gy of orthovoltage radiation. The percentage of cells in each phase of the cell cycle was determined at various times after irradiation using flow cytometry. All cell lines underwent a dose-dependent arrest in G2 phase after irradiation, but the resistant cell lines underwent a significantly longer arrest in G2 phase after irradiation than did the sensitive cell lines. In conjunction with other results from our laboratories, we suggest that this difference in G2 arrest may be the basis for the increased resistance of cells transfected with oncogenes to irradiation.

An exogenous albumin promoter can become silent in dedifferentiated hepatoma variants as well as intertypic hybrids

In order to evaluate the ability of an exogenous tissue-specific promoter to undergo the same dynamic changes in activity as the endogenous one, a 400-base pair fragment of the rat albumin proximal promoter, upstream of the bacterial gpt gene, has been introduced into rat hepatoma cells. Four clones containing a single integrated copy of the construct and producing substantial amounts of albumin and of xanthine phosphoribosyltransferase were isolated. These clones were subjected to two treatments known to result in silencing of the albumin gene: selection for dedifferentiated variants, and fusion with L-cell fibroblasts. In most cases, the albumin-negative progeny obtained no longer expressed the gpt gene: the exogenous promoter of 400 base pairs must contain the sequences required to respond to the mechanisms that block activity of the endogenous gene. However, exceptions were observed: the albumin-deficient variants of one clone remained xanthine phosphoribosyltransferase positive, and some of the albumin-negative hybrids from a different clone continued to produce xanthine phosphoribosyltransferase. These cases of dissociation in expression of the endogenous and the exogenous genes indicate that the site of integration of the alb-gpt construct in one clone renders the sequences insensitive to the mechanisms responsible for albumin gene silencing in dedifferentiated variants, and in the other clone to the mechanism of extinction. Consequently, the mechanisms causing gene silencing in variants and in intertypic hybrids must be different.

Genetic analysis of aflatoxin B1 activation in rat hepatoma cells

We present a strategy to elucidate the rate-limiting steps in activation of carcinogenic compounds by cytochromes P450. The principle was to select Reuber rat hepatoma cells for resistance to a procarcinogen. The hypothesis was that resistant cells should be systematically deficient in the P450 enzyme(s) involved in the activation process. Here we present an example of the use of this approach using aflatoxin B1 (AFB1), a potent hepatocarcinogen, as the selective agent. Parental cells as well as individual and pooled colonies selected for AFB1 resistance from three independent rat hepatoma lines were characterized for their content of 1) mRNA hybridizing to cDNA and/or oligonucleotide probes for cytochromes P450IIB1, P450IIB2 and albumin; and 2) aldrin epoxidase activity. Parental aflatoxin B1-sensitive cells were shown to express P450IIB1 but not P450IIB2. The majority of the aflatoxin B1-resistant clones failed to accumulate cytochrome P450IIB1 mRNA and expressed no or only very low aldrin epoxidase activity. Albumin mRNA levels remained unchanged, demonstrating that loss of expression of cytochrome P450IIB1 was not a consequence of a general dedifferentiation event. A revertant population showing restoration of both cytochrome P450IIB1 mRNA accumulation and aldrin epoxidase activity was fully sensitive to aflatoxin B1. The correlation between expression of cytochrome P450IIB1 and sensitivity to aflatoxin B1 in both parental cells and revertants strongly suggests that cytochrome P450IIB1 is a major contributor to the activation of aflatoxin B1 in rat hepatoma cells. The kind of strategy described here could be applied to other compounds that become cytotoxic for hepatoma cells following activation by cytochromes P450.

Activation of phenylalanine hydroxylase expression following genomic DNA transfection of hepatoma cells

Genomic DNA from cells producing the liver-specific enzyme phenylalanine hydroxylase (PAH) should contain, in active form, genes encoding regulators of PAH expression. We have transfected genomic DNA from PAH-producing rat hepatoma cells to PAH-deficient mouse hepatoma cells, and selected in tyrosine-deficient medium for cells producing the enzyme. The frequency of colonies obtained was similar to that for transfer of a single-copy gene. Genomic DNA from the primary transfectants permitted the isolation in tyrosine-free medium of secondary transfectants. Control experiments, using donor DNA from PAH-negative rat or mouse hepatoma cells also permitted the isolation of PAH-expressing cells, but at a frequency 10-30 times lower. The transfectants isolated in tyrosine-deficient selective medium all produced PAH mRNA. This transcript was from the previously silent mouse gene, which had not undergone amplification or gross rearrangement. Most of the transfectants contained less than 0.1% rat DNA. A search for other functions that might have been simultaneously activated was negative. It is concluded that the mouse transfectants acquired from the PAH+ rat donor some sequences whose presence permits activity of the previously silent PAH gene.

Interaction of trans-acting factors and re-expression of liver functions in hepatoma hybrid cells

The specific functions expressed by differentiated cells are extinguished when these cells are crossed with somatic cells of another histotype or with cells of the same differentiation that fail to express these functions: in rat hepatoma x mouse fibroblast hybrids, tyrosine aminotransferase (TAT) and phosphoenolypyruvate carboxykinase (PEPCK) activities are extinguished as they are in hybrids between the same rat hepatoma cell line and mouse hepatoma cells that do not express these two enzymes. The locus Tse-1 (tissue-specific extinguisher) on mouse chromosome 11 is responsible for the extinction of TAT and PEPCK in rat hepatoma x mouse fibroblast hybrids and loss of mouse chromosome 11 leads to re-expression of these two enzymes. We report here an analysis of rat hepatoma x mouse hepatoma hybrids that demonstrates that loss of mouse chromosome 11 is not necessary for re-expression of TAT and PEPCK. In view of the facts that Tse-1 is active in mouse hepatoma cells that do not express TAT and PEPCK and that the presence of only one active Tse-1 locus is sufficient to extinguish these functions in 2s rat hepatoma cells, we conclude that re-expression of TAT and PEPCK in rat hepatoma x mouse hepatoma hybrids is due to the epistatic action of tissue-specific trans-acting activators that override the Tse-1 effect.

The role of the H-ras oncogene in radiation resistance and metastasis

The sensitivity of tumor cells to the killing effects of ionizing radiation is thought to be one of the major determinants of curability of tumors in patients treated with radiation therapy. This paper reviews the evidence from our laboratory and other groups which supports a role for oncogenes in the induction of radioresistance in cultured mammalian cells. Primary rat embryo cells (REC) were chosen as a model system in which the effects on radiation resistance of the H-ras oncogene could be studied on a uniform genetic background. These cells offered several useful advantages. The cells prior to transformation are diploid and because they have been in culture only for a few passages prior to transformation with the oncogene it is unlikely that any preexisting mutation affecting radiation response could be present. Additionally, the use of REC permitted the study of the effects of synergism between oncogenes on the induction of the radioresistant phenotype. The results show that the activated H-ras oncogene induces radiation resistance in primary rat cells after transformation, but that the effect of the oncogene itself is small. However, the myc oncogene, which has no effect on radiation resistance by itself, appears to have a synergistic effect on the induction of radiation resistance by H-ras. Radiation resistance induced by H-ras plus myc is characterized by an increase in the slope of the curve at high doses but there is also a large effect within the shoulder region of the radiation survival curve. The AdenoE1A oncogene which will also act synergistically with ras in transformation assays plays a less clear-cut role in assays of radiation resistance. The H-ras oncogene is also known not only to transform cells but also to induce metastatic behavior in the tumors which form after these transformed cells are injected into syngeneic animals or nude mice. We have also shown in our primary rat embryo cell system that the induction of metastatic behavior in transformed cells, like the induction of radioresistance depends on a complex interaction between oncogenes and the cellular background. This evidence will be reviewed to demonstrate some of the analogies between radiation resistance and metastasis as examples of the complex alterations in cellular phenotype which occur after oncogene transfection.(ABSTRACT TRUNCATED AT 400 WORDS)

Synergistic effect of the v-myc oncogene with H-ras on radioresistance

Resistance of tumors to irradiation or chemotherapeutic agents is thought to be one of the reasons why patients who present with early malignancies may not be cured. Much is now known about the molecular mechanisms that underlie drug resistance, but until recently little was known about genetic contributions to radiation resistance. Some evidence now links oncogenes, particularly the ras family of oncogenes, to radiation resistance but heterogeneity between tumors and cell lines has complicated this analysis. Primary rat embryo cells have been chosen as a model system in which the effects on radiation resistance of the H-ras oncogene could be studied on a uniform genetic background. These cells offer several useful advantages. The cells prior to transformation are diploid, and because they have been in culture only for a few passages prior to transformation with the oncogene it is unlikely that any preexisting mutation affecting radiation response could be present. Additionally, the use of rat embryo cells permitted the study of the effects of a second oncogene on the appearance of the radioresistant phenotype. The results show that the activated H-ras oncogene is associated with radiation resistance in primary rat cells after transformation but that the effect of the oncogene by itself is small. However, the oncogene v-myc, which has no effect on radiation resistance by itself, has a synergistic effect on radiation resistance with H-ras. There appear to be differences in the phenotype of radiation resistance associated with these two forms of transfectants. Thus, radiation resistance seen with H-ras by itself is characterized by a change in the slope of the radiation survival curve at high radiation doses but little or no change within the should region of the radiation survival curve. Radiation resistance seen in H-ras plus v-myc transformants is also characterized by an increase in the slope of the curve at high doses but there is also a large effect within the shoulder region of the radiation survival curve. These studies led to the following conclusions: (a) the radioresistant phenotype is not due to preexisting genetic heterogeneity in the cells prior to transfection; (b) the radiation resistant phenotype of cells transformed by H-ras is seen to a greater degree in cells which also contain the v-myc oncogene; (c) the v-myc oncogene may play an important role in the phenotype of radiation resistance at low doses that is within the range most critical for clinical practice.

Assignment of the rat genes coding for phenylalanine hydroxylase (PAH), tyrosine aminotransferase (TAT), and pyruvate kinase (PKL) to chromosomes 7, 19, 2, respectively

A panel of hybrid clones segregating rat chromosomes in a mouse background was used to determine the chromosomal localization of three genes specifically expressed in hepatocytes. The phenylalanine hydroxylase, tyrosine aminotransferase, and pyruvate kinase genes were assigned to rat chromosomes 7, 19, and 2, respectively.

Establishment of mouse and rat hepatoma cell clones showing stable expression of rabbit cytochrome P450 IA2

Cytochrome P450 IA2, a liver-specific member of the 3-methylcholanthrene-inducible family, is never detected in established cell lines. With the aim of isolating cells stably producing this protein, we have used rat and mouse hepatoma cells as recipients in transfection experiments involving rabbit cytochrome P450 IA2 cDNA. We report here the isolation of five hepatoma cell clones expressing functional P450 IA2. The level of expression is comparable to that found in COS cells transiently transformed by other P450 cDNAs. It ranges between 0.4 and 1.6 pmol P450 IA2/mg total cell protein.

The rat albumin promoter: cooperation with upstream elements is required when binding of APF/HNF1 to the proximal element is partially impaired by mutation or bacterial methylation

We have characterized in the accompanying paper (P. Herbomel, A. Rollier, F. Tronche, M.-O. Ott, M. Yaniv, and M. C. Weiss, Mol. Cell. Biol. 9:4750-4758, 1989) six different elements in the albumin promoter. One of them, the proximal element (PE), is the binding site for a strictly liver specific factor, APF/HNF1. This binding site contains a bacterial DAM DNA methylase methylation target sequence which, when methylated, decreases the affinity of the protein for this element. When the different albumin promoter constructions were prepared in an Escherichia coli deoxyadenosine methylase-negative strain, the respective contributions of the elements to the overall promoter activity were strikingly different. An intact proximal element plus the TATA box gave almost full transcriptional activity in transient transfection experiments and only in differentiated hepatoma cells of line H4II, whereas the distal elements (distal element III [DEIII], the NF1-binding site DEII, and the E/CBP-binding site DEI) had become essentially dispensable. Mutations affecting the CCAAT box showed only a two- to threefold decrease. When PE was methylated, mutated, or replaced by the homologous element from the alpha-fetoprotein gene, activity in the context of the short promoter (PE plus the TATA box) was abolished. However, activity was restored in the presence of the upstream elements, showing that cooperation with factors binding to the CCAAT box and distal elements favors the functional interaction of the liver-specific APF/HNF1 factor with lower-affinity binding sites.

The rat albumin promoter is composed of six distinct positive elements within 130 nucleotides

No fewer than six different positive regulatory elements concentrated within 130 base pairs constitute the rat albumin promoter, which drives highly tissue specific transcription in rat hepatoma cells in culture. Inactivation of each element led to a decrease in transcriptional efficiency: from upstream to downstream, 3- to 4-fold for distal elements III and II, 15-fold for distal element I, and 50-fold for the CCAAT box and the proximal element (PE). Three of these elements, distal elements III and II and, more crucially, the PE, were found to be involved in the tissue-specific character of transcription, with an additional negative regulation possibly superimposed at the level of the PE. Finally, our mapping of these regulatory elements in vivo entirely coincided with footprint data obtained in vitro, thereby allowing the tentative assignment of specific factors to the effects observed in vivo.

Biochemical and genetic analysis of the nifUSVWZM cluster from Azotobacter vinelandii

Azotobacter vinelandii genes contained within the major nif-cluster and designated orf6, nifU, nifS, nifV, orf7, orf8, nifW, nifZ, nifM, and orf9 are organized into at least two overlapping transcriptional units. Nitrogenase derepressed crude extracts of Azotobacter vinelandii mutant strains having individual deletions located within nifU, nifS, nifV, nifW, nifZ, or nifM were examined for nitrogenase component protein activities. The results of these experiments indicated that, in A. vinelandii, the nifU, nifS and nifM gene products are required for the full activation or the catalytic stability of the nitrogenase Fe protein. Deletion of the nifV gene resulted in lower MoFe protein activity, probably resulting from the accumulation of an altered FeMo-cofactor. The nifW and nifZ gene products were required for the full activation or catalytic stability of the MoFe protein. Deletion of nifZ alone or nifM alone did not appear to affect FeMo-cofactor biosynthesis. However, deletion of both nifZ and nifM eleminated either FeMo-cofactor biosynthesis or the insertion of FeMo-cofactor into the apo-MoFe protein. Other genes contained within the nifUSVWZM gene cluster (orf6, orf7, orf8, and orf9) were not required for Mo-dependent diazotrophic growth.

Conditions required for activation of the mouse albumin or alpha-fetoprotein gene in hybrids between mouse lymphoblastoma and rat hepatoma cells

Activation of two previously silent mouse hepatic genes has been investigated in hybrid cells between pseudodiploid mouse lymphoblastoma cells and hyperdiploid or hypertetraploid rat hepatoma cells. In this material, activation of the mouse albumin gene is a frequent event, whereas activation of mouse alpha-fetoprotein (AFP) occurs only in those cells that produce large amounts of albumin. Quantitative tests of hybrid populations for the activated proteins and their mRNAs revealed the expected sizes and structures: moreover, as in hepatoma cells, the amount of both rat and mouse albumin produced was directly proportional to the intracellular concentration of the corresponding mRNA. The cellular environment required for activation of the liver-specific genes was investigated by cell-by-cell analysis of each hybrid clone. Immunostaining for the presence of rat and mouse albumin and mouse AFP revealed unexpected heterogeneity in the phenotypes of the hybrid populations, which were found to contain cells that: (a) failed to express either of the proteins; (b) produced all three; (c) produced both rat and mouse albumin; or (d) produced rat albumin only. Karyotypic analysis indicated that the hybrid-cell phenotype depended on parental chromosome ratios rather than absolute numbers of chromosomes. It was found for albumin and mouse AFP that the fraction of immunostained cells was equal to the fraction of metaphases that contained a minimal rat-to-mouse chromosome ratio of 2.5 and 9, respectively. It is concluded that in those hybrids, expression of liver-specific genes is regulated by extinguishers, but in a dose-dependent fashion, suggesting the intervention of antagonistic activators from the rat hepatoma chromosomes.

Efficient one-step selection of hepatoma cell variants of a variety of phenotypes by use of aflatoxin B1

We have developed a method to select for rat hepatoma cells that fail to express hepatocyte-specific functions. Well-differentiated cells descended from the H4IIEC3 hepatoma line express aldrin epoxidase (AE) activity, an indicator of the liver-specific forms of cytochromes P450 and, concurrently, are able to activate the procarcinogen aflatoxin B1 (AFB1) into highly toxic metabolites. Thus, differentiated hepatoma cells are highly sensitive to AFB1, while dedifferentiated derivatives, which fail to express AE activity, are resistant. Exposure of differentiated Fao cells to 10 microM AFB1 for 24 h permits the isolation, at a frequency of 5 x 10(-5), of resistant colonies that exhibit strongly reduced AE activity. Strikingly, various morphological types can be observed. In more than 90% of the colonies, cells are morphologically similar to the original differentiated cells and accumulate all liver-specific mRNAs examined in amounts comparable to Fao cells. Moreover, they are able to carry out gluconeogenesis, as judged by their capacity to grow in glucose-free medium. For a minor fraction of colonies, the cells exhibit nonhepatic morphology. These cells fail to express three or more of the liver functions and are not able to proliferate in glucose-free medium. Our results demonstrate that the use of AFB1 constitutes a simple and efficient single-step selective method for obtaining variant hepatoma cells of a wide variety of phenotypes.

Phenobarbital, dexamethasone and benzanthracene induce several cytochrome P450 mRNAs in rat hepatoma cells

Hepatoma cells derived from the Reuber H35 rat hepatoma express cytochrome P450 enzymes of two major families: polycyclic aromatic hydrocarbon-inducible forms are found in both differentiated and dedifferentiated cells while phenobarbital (PB)-inducible forms are found only in differentiated cells. We report here that (i) benzanthracene and PB induce P450 c mRNA in differentiated and dedifferentiated cells and (ii) dexamethasone and PB induce P450 b/e and/or P450 PB1 mRNAs in differentiated cells but not in dedifferentiated cells.

Products of the iron-molybdenum cofactor-specific biosynthetic genes, nifE and nifN, are structurally homologous to the products of the nitrogenase molybdenum-iron protein genes, nifD and nifK

The genes from Azotobacter vinelandii, which are homologous to the iron-molybdenum cofactor biosynthetic genes, nifE and nifN, from Klebsiella pneumoniae, have been cloned and sequenced. These genes comprise a single transcription unit and are located immediately downstream from the nitrogenase structural gene cluster (nifHDK). DNA sequence analysis has revealed that the products of the nifE and nifN genes contain considerable homology when compared with the nifD (MoFe protein alpha subunit) and the nifK (MoFe protein beta subunit) gene products, respectively. These striking sequence homologies indicate a structural and functional relationship between a proposed nifEN product complex and the nitrogenase MoFe protein as well as imply an ancestral relationship between these gene clusters. The isolation and characterization of strains which contain deletions within the nifEN gene cluster demonstrate a role for these products in iron-molybdenum cofactor biosynthesis in A. vinelandii.

Tissue-specific expression of the rat albumin gene: genetic control of its extinction in microcell hybrids

Numerous studies of cell hybrids have indicated that somatic cells produce negative regulators (extinguishers) that prevent the expression of functions foreign to their own differentiation. Here, we report genetic evidence of such control. In microcell hybrids between well-differentiated rat hepatoma cells and microcells of mouse fibroblast L cells, the extinction of albumin synthesis is directly related to the presence of a single specific chromosome of the mouse fibroblast parent. The expression of several other hepatic functions is not affected. Transfection of these hybrids with a recombinant plasmid, containing a tissue-specific control element of the upstream region of the rat albumin gene linked to coding sequences of the chloramphenicol acetyltransferase gene, reveals that extinction acts on or via this cis-control element.

An ultrastructural study of rat hepatoma cells in culture, their variants and revertants

We compared the ultrastructure of a well-differentiated rat hepatoma line (H4II) and its clonal progeny, including dedifferentiated variant cells, and revertants of the variants in which the spectrum of hepatocyte-specific functions is again expressed. The cells of the original differentiated lines and the revertants were very similar to one another. In addition, they exhibited some of the characteristics of fetal and neonatal hepatocytes. Variant cells which fail to express hepatocyte functions showed a wide range of morphological alterations accompanied by generalized disorganization. It is concluded that the loss of hepatocyte differentiation in the variants is not associated with a uniform morphological type, and that a wide range of ultrastructural phenotypes can be generated in the progeny of a single neoplastic but well-differentiated hepatocyte. Also, the expression of hepatocyte functions only occurs within a limited and organized morphological framework that includes features of young hepatocytes.

Plasma-protein production by rat hepatoma cells in culture, their variants and revertants

A series of subclones of the H4II line of the Reuber H35 rat hepatoma produce substantial amounts of three plasma proteins, transferrin, alpha 1-antitrypsin and fibrinogen. Immunocytochemical staining demonstrated that each of these proteins is synthesized by essentially every cell of these cell populations. Cells of dedifferentiated variant clones either cease to produce the proteins, or exhibit a substantial reduction that is accompanied by variability in the synthetic activity of individual cells of the population. As previously observed with regard to angiotensinogen production, the variant clones clearly divide into two categories: those that show only a reduction in synthesis are able to give rise to revertants, whereas the negative clones fail to do so. Revertant cells exhibit a dramatic restoration of the synthesis of plasma proteins, which in some cases, exceeds by severalfold the rates seen in the differentiated clones of origin. In addition, the revertant cells synthesize alpha-fetoprotein, a function that is not expressed by H4II cells or its daughter subclones. Immunocytochemical staining revealed that, with regard to several plasma proteins including albumin, fibrinogen and alpha-fetoprotein, the cell populations of revertant clones are very heterogeneous, for only a fraction of the cells synthesizes each protein. Hybrid cells resulting from several types of crosses, exhibited extinction of the plasma proteins, the exception being transferrin, whose production was maintained, but at a reduced level and in only a fraction of the cells. Taken together, our results show that the expression of albumin and transferrin can be dissociated from one to another, and from that of fibrinogen, alpha 1-antitrypsin and angiotensinogen.

Activation of a silent gene is accompanied by its demethylation

The phenomenon of gene activation by cell fusion makes it possible to study a gene when it passes from a silent to an active state. The relationship between methylation and activation of the mouse albumin gene has been investigated in two types of hybrid clones: mouse lymphoblastoma--rat hepatoma hybrids where activation is very frequent, and mouse L-cell--rat hepatoma hybrids where activation is a rare event. Analysis of the methylation pattern of seven MspI/HpaII sites that occur along the first 8000 bases of the mouse albumin gene has been performed. The entire 5' region is unmethylated only in albumin-producing cells (adult liver and hepatoma); in non-hepatic cells this region is heavily methylated. In hybrids between rat hepatoma cells and mouse cells of mesenchymal origin, the only regular change is the demethylation of the most 5' site (M1), which is systematically observed in clones where expression of the mouse albumin gene has been activated. Demethylation of this site, like activation of the mouse albumin gene, is gene dosage-dependent; it is systematic in the lymphoblastoma--hepatoma hybrids and rare in L-cell--hepatoma hybrids. We conclude that demethylation of this site is tightly coupled with activation of the gene and may well be a necessary prerequisite for activation.

Albumin extinction followed by de novo methylation of its gene in somatic hybrids of a rat hepatoma

We have previously identified an Msp I site at the 5' end of the rat albumin gene whose undermethylation is necessary but not sufficient for stable albumin expression in rat hepatoma cells. We have also shown that the extinction of albumin expression in somatic hybrids is not the result of methylation at this site, since for two different crosses, rapid extinction was found to occur in the absence of any de novo methylation of the previously active gene. In the present study, we examine albumin expression and albumin gene methylation for independent hybrid clones isolated from crosses between albumin expressing rat hepatoma cells and cells of two different non-expressing lines. The cells from hybrid clones of both crosses are characterized by stable extinction of albumin expression. Moreover, we find that de novo methylation of the "extinguished" albumin gene can occur in somatic hybrids, but only some weeks after the gene has ceased to be expressed.

Tissue-specific expression is conferred by a sequence from the 5′ end of the rat albumin gene

We have constructed a transient expression vector containing 400 bp of rat albumin gene immediate 5'-flanking sequences inserted 5' to the bacterial enzyme chloramphenicol acetyl transferase (CAT). We have transfected various clones of rat hepatoma cells representing different states of expression of the liver phenotype with this vector (pALB-cat) and also with two control vectors containing viral promoters (pSVE-cat and pRSV-cat), and measured activity of the bacterial enzyme CAT in cellular extracts 48 h later. The albumin flanking sequences are able to direct highly efficient CAT expression, compared with the control vectors, only in cells which express their own albumin gene: the albumin-negative hepatoma cells are at least 100 times less efficient in expressing CAT after transfection with the pALB-cat plasmid than are the albumin-positive ones. An unexpected result of our study is the total inability of the rat albumin flanking sequences to direct expression in albumin-producing mouse hepatoma cells.

A study of chromosomal changes associated with amplified dihydrofolate reductase genes in rat hepatoma cells and their dedifferentiated variants

We have examined the karyological consequences of dihydrofolate reductase gene amplification in a series of six rat hepatoma cell lines, all derived from the same clone. Cells of three of these lines express a series of liver-specific functions whereas those of three others fail to express these functions. Cells of each line have been subjected to stepwise selection for methotrexate resistance and, in most cases, resistance is associated with a 40-50-fold amplification of sequences hybridizing to a dihydrofolate reductase cDNA probe. In one line no modified chromosome is observed, whereas in two others the amplified genes are associated with an expanded chromosomal region. R-banding analysis of these karyotypes showed that few changes have occurred. These observations apply to two of the well-differentiated lines, and to a variant able to revert to the differentiated state. In contrast, in the two stably dedifferentiated hepatoma cell lines, amplified dihydrofolate reductase genes are found on large chromosomes of variable size, on ring chromosomes, and on chromosomes containing terminal, median, or multiple centromeres. We conclude that the nature of the chromosomal changes associated with dihydrofolate reductase gene amplification are the result of differences in cell lines rather than in the protocols employed for selection.