The involvement of a stress-activated pathway in equine influenza virus-mediated apoptosis

We have shown elsewhere that equine-2 influenza virus (EIV; subtype H3N8) induced pronounced cell death in infected cells through apoptosis as demonstrated by DNA fragmentation assay and a combined TUNEL and immunostaining scheme. In this study, we investigated the mechanism of EIV-mediated cytotoxicity on a permissive mammalian epithelial cell line, Madin-Darby canine kidney (MDCK) cells. EIV infection increased the cellular levels of oxidative stress and c-Jun/AP-1 protein (which is known to be affected by oxidative stress), as well as its DNA binding activity. Increased production of TGF-beta1, an inducer of c-Jun N-terminal kinase or stress-activated protein kinase (JNK/SAPK) activation, was also detected in EIV-infected MDCK cells. It has been reported that TGF-beta may initiate a signaling cascade leading to JNK/SAPK activation. Addition of c-Jun antisense oligodeoxynucleotide, antioxidant N-acetyl-cysteine (NAC), JNK/SAPK inhibitor carvedilol, or TGF-beta-neutralizing antibody effectively blocked c-Jun/AP-1 upregulation and TGF-beta1 production mediated by EIV infection. These treatments also attenuated EIV-induced cytopathogenic effects (CPE) and apoptosis. Our results suggest that a stress-activated pathway is involved in apoptosis mediated by EIV infection. It is likely that EIV infection turns on the JNK/SAPK cascade, which modulates the activity of apoptosis-promoting regulatory factor c-Jun/AP-1 and epithelial growth inhibitory cytokine TGF-beta.

The highly lipophilic DNA topoisomerase I inhibitor DB-67 displays elevated lactone levels in human blood and potent anticancer activity

The novel silatecan 7-t-butyldimethylsilyl-10-hydroxycamptothecin (DB-67) is 25- to 50-times more lipophilic than camptothecin and readily incorporates into lipid bilayers. Using the method of fluorescence anisotropy titration, we determined that DB-67 bound to small unilamellar vesicles composed of dilaurylphosphatidylcholine (DLPC) with an association constant (K value) of 5000 M(-1). This association constant is significantly higher than the K(DLPC) value observed for camptothecin (K(DLPC) value of 110 M(-1)). Using HPLC methods, we demonstrated that the presence of liposomal membranes readily stabilize the lactone form of DB-67. At drug and lipid concentrations of 10 microM and 0.3 mM, respectively, the lactone form of DB-67 persisted in liposome suspension after 3 h of incubation at 37 degrees C. Thus an advantage of a liposomal formulation of DB-67 is that the presence of lipid bilayers assists with stabilizing the key pharmacophore of the agent. The highly lipophilic character of DB-67, in combination with its 10-hydroxy moiety (which functions to enhance lactone stability in the presence of human serum albumin), results in DB-67 having superior stability in human blood with a percent lactone at equilibrium value of 30 [Cancer Res. 59 (1999) 4898; J. Med. Chem. 43 (2000) 3970]. Potent cytotoxicities against a broad range of cancer cells were observed for DB-67, indicating that DB-67 is of comparable potency to camptothecin. The impressive human blood stability and cytotoxicity profiles for DB-67 indicate it is an excellent candidate for comprehensive in vivo pharmacological and efficacy studies. Based on these promising attributes, DB-67 is currently being developed under the NCI RAID program. Due to its potent anti-topoisomerase I activity and its intrinsic blood stability, DB-67 appears as an attractive novel camptothecin for clinical development.

Histone deacetylase inhibitors promote apoptosis and differential cell cycle arrest in anaplastic thyroid cancer cells

Little information exists concerning the response of anaplastic thyroid carcinoma (ATC) cells to histone deacetylase inhibitors (HDAIs). In this study, the cellular response to the histone deacetylase inhibitors, sodium butyrate and trichostatin A, was analyzed in cell lines derived from primary anaplastic thyroid carcinomas. HDAIs repress the growth (proliferation) of ATC cell lines, independent of p53 status, through the induction of apoptosis and differential cell cycle arrest (arrested in G1 and G2/M). Apoptosis increases in response to drug treatment and is associated with the appearance of the cleaved form of the caspase substrate, poly-(ADP-ribose) polymerase (PARP). Cell cycle arrest is associated with the reduced expression of cyclins A and B, the increased expression of the cyclin-dependent kinase inhibitors, p21(Cip1/WAF1) and p27Kip1, the reduced phosphorylation of the retinoblastoma protein (pRb), and a reduction in cdk2 and cdk1-associated kinase activities. In ATC cells overexpressing cyclin E, drug treatment failed to replicate these events. These results suggest that growth inhibition of ATC cells by HDAIs is due to the promotion of apoptosis through the activation of the caspase cascade and the induction of cell cycle arrest via a reduction in cdk2- and cdk1-associated kinase activities.

Butyrate alters the expression and activity of cell cycle components in anaplastic thyroid carcinoma cells

Anaplastic thyroid carcinoma (ATC) is the most malignant and aggressive form of thyroid cancer. Most patients die within months of diagnosis, primarily due to the absence of effective chemotherapeutic strategies. Identifying alternative therapies is necessary to increase long-term survival. Butyrate elicits a number of responses from cancer cells both in vitro and in vivo including growth repression, cell cycle arrest, differentiation, and apoptosis. Even though many types of cancer cells have been studied, little is known of the response of ATC cells to this drug. In this study, we report that butyrate induces differential cell cycle arrest (arrest in G1 and G2/M phases) in an ATC cell line that correlates with changes in the expression, phosphorylation, and activity of key components of the cell cycle machinery. Exposure to butyrate increases the expression of the cyclin-dependent kinase inhibitors, p21/Cip1 and p27/Kip1, decreases the expression of cyclin A and cyclin B, inhibits the phosphorylation of the retinoblastoma protein (pRb), and decreases the activity of cdk1 and cdk2-associated kinases. These results suggest that butyrate may be useful in the clinical treatment of ATC.

The novel silatecan 7-tert-butyldimethylsilyl-10-hydroxycamptothecin displays high lipophilicity, improved human blood stability, and potent anticancer activity

We describe the rational design and synthesis of B- and A, B-ring-modified camptothecins. The key alpha-hydroxy-delta-lactone pharmacophore in 7-tert-butyldimethylsilyl-10-hydroxycamptothecin (DB-67, 14) displays superior stability in human blood when compared with clinically relevant camptothecin analogues. In human blood 14 displayed a t(1/2) of 130 min and a percent lactone at equilibrium value of 30%. The tert-butyldimethylsilyl group renders the new agent 25-times more lipophilic than camptothecin, and 14 is readily incorporated, as its active lactone form, into cellular and liposomal bilayers. In addition, the dual 7-alkylsilyl and 10-hydroxy substitution in 14 enhances drug stability in the presence of human serum albumin. Thus, the net lipophilicity and the altered human serum albumin interactions together function to promote the enhanced blood stability. In vitro cytotoxicity assays using multiple different cell lines derived from eight distinct tumor types indicate that 14 is of comparable potency to camptothecin and 10-hydroxycamptothecin, as well as the FDA-approved camptothecin analogues topotecan and CPT-11. In addition, cell-free cleavage assays reveal that 14 is highly active and forms more stable top1 cleavage complexes than camptothecin or SN-38. The impressive blood stability and cytotoxicity profiles for 14 strongly suggest that it is an excellent candidate for additional in vivo pharmacological and efficacy studies.

Translational control of malignancy: the mRNA cap-binding protein, eIF-4E, as a central regulator of tumor formation, growth, invasion and metastasis

Recent studies have implicated the mRNA cap-binding protein, eIF-4E, as a key regulator of malignant progression. Indeed, the major intracellular signaling pathways involved in tumor growth and malignancy, the MAP kinase and PI3 kinase pathways, induce eIF-4E activity. Furthermore, immunohistochemical analyses have revealed that eIF-4E is overexpressed and related to disease progression in human cancers of the colon, head and neck, and breast. In experimental tumors, manipulation of eIF-4E function profoundly affects not only tumorigenesis but also tumor invasion and metastasis. While increasing global protein synthesis rates, the increased activity of eIF-4E that typifies both human and experimental tumors disproportionately enhances the translation of a specific array of potent growth regulatory and malignancy-related proteins, including c-myc, cyclin D1, ornithine decarboxylase, vascular endothelial growth factor, basic fibroblast growth factor and others. Herein, we review the data supporting the notion that, by coordinately upregulating the translation of numerous malignancy-related proteins, eIF-4E plays a pivotal role in regulating not only tumor growth, but also invasion and metastasis.

A dominant-negative mutant of the platelet-derived growth factor A-chain increases survival of hamsters implanted intracerebrally with the highly invasive CxT24-neo3 glioblastoma cell

Evidence is accumulating to suggest a role for PDGF in stimulating malignant growth in astrocytoma, although it has been obtained using model systems (growth in 2-dimensional cell culture, athymic nude mice) that do not assess the complex interactions of these tumors with normal brain tissue. In the current study, the highly invasive hamster glioblastoma cell line CxT24-neo3 was used as a model to study the role of platelet-derived growth factor (PDGF) in mediating malignant growth both in vitro and in vivo when implanted directly into the right lateral ventricle of the brain. Co-expression of PDGF B-chain mRNA and PDGF alpha-receptors was detected in these cells, indicating potential for autocrine activation of their growth. CxT24-neo3 cells transfected with wild-type and receptor binding-deficient forms of the PDGF A- and B-chains displayed alterations in their abilities to grow as three-dimensional spheroids, with overexpression of wild-type B-chain resulting in increased spheroid formation, but a decreased rate of spheroid growth. Influence of these PDGF polypeptides on tumor invasion and survival time in vivo was evaluated following implantation of these spheroids in the brain. While all hamsters implanted with control spheroids died within 21 d (average 17 d), those implanted with cells expressing the receptor binding-deficient A-chain survived for much greater periods of time (average 80 d). Modest increases in survival were also seen in cells stably expressing wild-type A-chain (25 d) and mutant B-chain (26 d) proteins. The present study suggests an important role of PDGF in mediating the malignant growth of the CxT24-neo3 cell line in cerebral cortex, possibly via paracrine interactions with normal cortical cell types (i.e., glia, neurons).

Distinct patterns of E-cadherin CpG island methylation in papillary, follicular, Hurthle's cell, and poorly differentiated human thyroid carcinoma

Expression of the invasion/metastasis suppressor, E-cadherin, is diminished or lost in thyroid carcinomas. Yet, mutational inactivation of E-cadherin is rare. Herein, we show that this loss is associated with hypermethylation of the E-cadherin 5' CpG island in a panel of human thyroid cancer cell lines. This aberrant methylation is evident in 83% of papillary thyroid carcinoma, 11% of follicular thyroid carcinoma, 40% of Hurthle's cell carcinoma, and 21% of poorly differentiated thyroid carcinomas. Contrary to previous reports, the majority of these poorly differentiated thyroid carcinomas express E-cadherin, but often within the cytoplasm rather than at the cell surface. Together, our data indicate that the invasion/metastasis suppressor function of E-cadherin is frequently compromised in human papillary, Hurthle's cell, and poorly differentiated thyroid carcinoma by epigenetic and biochemical events.

Two new human neuroblastoma cell lines exhibiting tumorigenesis and metastasis in the nude mouse model

BACKGROUND

Human neuroblastoma cell lines are notoriously difficult to establish in culture and use in murine hosts.

MATERIALS AND METHODS

Two new human neuroblastoma cell lines, NK and ND, were established and studied for growth patterns in nude mice, growth in soft agar, cell cycle analysis, apoptosis (Hoechst- merocyanine 540 test), metalloproteinase expression (zymograms), and morphological differentiation by dibutyryl cyclic AMP (dCAMP).

RESULTS

Both cell lines formed tumors in 6/9 nude mice within 5-31 days after subcutaneous inoculation, and metastases after intravenous tail vein injection. Both grew in soft agar. DCAMP induced morphologic differentiation in both, and inhibited cell culture growth without apoptosis. Zymograms of supernatants from cultures revealed 72-kDa metalloproteinase and higher molecular bands that did not change with dCAMP treatment. Cultures derived from murine metastatic foci exhibited 72, 82 and 85-kDa proteins, with strong 92-kDa bands after dCAMP treatment.

CONCLUSION

New human neuroblastoma cell lines were established that are easily used in nude mice, and express metalloproteinases.

Translation of ODC mRNA and polyamine transport are suppressed in ras-transformed CREF cells by depleting translation initiation factor 4E

Rapid tumor growth and metastasis require increased polyamine metabolism, which is coordinately regulated by ornithine decarboxylase (ODC) and the polyamine transporter. Both activities are stimulated by ras signalling and are dependent upon protein biosynthesis. T24ras oncogene expression in rat embryo fibroblasts (CREFT24) induces cellular transformation and malignancy, in part, by stimulating the rate-limiting translation initiation factor, eIF-4E. CREFT24 expressing antisense RNA to eIF-4E (AS4E) have markedly decreased tumor growth rates and metastatic capacity, without altered monolayer growth rates. Herein, we demonstrate that in AS4E, ODC is translationally suppressed resulting in decreased ODC activity. Additionally, exogenous polyamine uptake is suppressed in AS4E cells indicating that AS4E can neither generate nor import the polyamines necessary to support rapid tumor growth. These data provide evidence that eIF-4E is the link between ras-induced malignancy and increased polyamine metabolism and support the hypothesis that eIF-4E plays a pivotal role in mediating ras-induced malignancy.

Elevated expression of eIF4E and FGF-2 isoforms during vascularization of breast carcinomas

The translation initiation factor eIF4E is a novel protooncogene found over expressed in most breast carcinomas (Kerekatte et al., 1995), but the pathology where this elevation is initially manifested and its possible role in cancer progression are unknown. We report that eIF4E is markedly increased in vascularized malignant ductules of invasive carcinomas, whereas necrotic and avascular ductal carcinomas in situ display significantly lower levels. eIF4E facilitates the synthesis of FGF-2, a powerful tumor angiogenic factor. Conversely, reducing eIF4E with antisense RNA in MDA-435 cells suppresses their tumorigenic and angiogenic properties, consistent with loss of FGF-2 synthesis. These findings suggest a causal role for eIF4E in tumor vascularization.

Expression and function of the leucine zipper protein Par-4 in apoptosis

The prostate apoptosis response-4 (par-4) gene was identified by differential screening for genes that are upregulated when prostate cancer cells are induced to undergo apoptosis. The par-4 gene is induced by apoptotic signals but not by growth-arresting, necrotic, or growth-stimulatory signals. The deduced amino acid sequence of par-4 predicts a protein with a leucine zipper domain at its carboxy terminus. We have recently shown that the Par-4 protein binds, via its leucine zipper domain, to the zinc finger domain of Wilms' tumor protein WT1 (R. W. Johnstone et al., Mol. Cell. Biol. 16:6945-6956, 1996). In experiments aimed at determining the functional role of par-4 in apoptosis, an antisense par-4 oligomer abrogated par-4 expression and activator-driven apoptosis in rat prostate cancer cell line AT-3, suggesting that par-4 is required for apoptosis in these cells. Consistent with a functional role for par-4 in apoptosis, ectopic overexpression of par-4 in prostate cancer cell line PC-3 and melanoma cell line A375-C6 conferred supersensitivity to apoptotic stimuli. Transfection studies with deletion mutants of Par-4 revealed that full-length Par-4, but not mutants that lacked the leucine zipper domain of Par-4, conferred enhanced sensitivity to apoptotic stimuli. Most importantly, ectopic coexpression of the leucine zipper domain of Par-4 inhibited the ability of Par-4 to enhance apoptosis. Finally, ectopic expression of WT1 attenuated apoptosis, and coexpression of Par-4 but not a leucine zipperless mutant of Par-4 rescued the cells from the antiapoptotic effect of WT1. These findings suggest that the leucine zipper domain is required for the Par-4 protein to function in apoptosis.

Quantitative and qualitative differences in growth, invasion and lung colonization of an anaplastic and a papillary human thyroid cancer cell line in vitro and in vivo

Invasion and metastasis remain major reasons for failure of anti-cancer therapy. Cell lines derived from human carcinomas are frequently used to investigate the molecular mechanisms that underlie invasion and metastasis. Unfortunately many of these cell lines do not retain the malignant characteristics of their parental tumors. We therefore conducted a series of experiments in vivo and in vitro to identify which aspects of malignancy of a papillary (NPA'87) and an anaplastic (DR090-1) thyroid carcinoma were consistent with the pathology of the parental tumor types. We evaluated tumor growth, invasion and metastasis of DRO90-1 and NPA'87 in vivo following inoculation of the tumor cells under the dermis, under the renal capsule and into the lateral tail vein of nude mice. This evaluation in vivo showed that the anaplastic carcinoma had a faster growth rate compared with the papillary carcinoma. Furthermore, the papillary carcinoma cells could destroy and infiltrate surrounding tissue but were not capable of extravasation and colonization of lung tissue. The anaplastic cells formed lung nodules following injection into the tail vein of nude mice. This lung colonizing capability of DRO90-1 correlated with their capacity to secrete an active 62 kDa gelatinase and to migrate through reconstituted basement membrane in vitro.

Phospholipases A2 in ras-transfected fibroblasts

Phospholipase A2 (PLA2) generated lipid biomediators can facilitate neoplastic progression. Specific PLA2 alterations associated with ras oncogene expression were determined by comparison of PLA2 activities in nontumorigenic rat embryo fibroblasts (CREF cells) and their tumorigenic ras oncogene-transfected counterparts (CREF-T24 cells). The high molecular mass cytosolic PLA2 activity is 2-3 fold higher in CREF-T24 cells as compared to CREF cells. Western blotting analyses indicate increases in the level of this enzyme and the proportion which migrates with phosphorylated enzyme in CREF-T24 cells. A PLA2 activity, with the characteristics of a group II PLA2, is readily detectible in particulate fractions from CREF-T24 cells following ammonium sulfate extraction/cation ion exchange chromatography. In contrast, this activity is minimal in similarly prepared CREF cell samples. While the CREF-T24 cells have increases in two PLA2 activities associated with the release of arachidonic acid, the CREF-T24 and CREF cells are similar with respect to Ca2+ independent, particulate fraction-associated PLA2 activities.

Reduction of translation initiation factor 4E decreases the malignancy of ras-transformed cloned rat embryo fibroblasts

Expression of the T24ras oncogene induces malignancy (tumor growth, invasion and metastasis) in cloned rat embryo fibroblasts (CREF T24). In CREF T24, the rate of phosphorylation of eukaryotic translation initiation factor 4E (eIF-4E) is increased, resulting in increased protein synthesis rates. We have recently shown that reducing the protein levels of eIF-4E in CREF T24 (AS4E line) markedly decreases soft-agar colonization, increases tumor latency periods and increases tumor doubling times without significantly altering monolayer growth. In this study, cells with reduced eIF-4E had delayed and reduced invasiveness and decreased experimental metastasis. Furthermore, reduced eIF-4E levels correlated with decreased expression of the metastasis-associated 92-kDa collagenase type-IV and exon-6 variants of the CD44 adhesion molecule [CD44(6v)]. Reduced eIF-4E levels correlated inversely with increased levels of the putative metastasis-suppressor protein nm23. Cell lines established from AS4E tumors and lung metastases exhibited increased levels of eIF-4E protein and protein synthesis rates compared to the AS4E line. Tumor-derived AS4E had the shortened tumor latency periods of CREF T24 but displayed the slow tumor-growth rates of AS4E. Tumor-derived AS4E exhibited the metastatic capacity of CREF T24 controls. Furthermore, tumor- and lung-nodule-derived AS4E expressed levels of CD44 (6v) and the 92-kDa collagenase type IV comparable to CREF T24 and displayed reduced levels of nm23 relative to AS4E. These results demonstrate that eIF-4E is an important effector molecule involved in oncogenic p21ras-induced malignant transformation.

Inhibition of collagenolytic activity relates to quantitative reduction of invasion in vitro in a c-Ha-ras transfected glial cell line

The function of proteases in brain tumor invasion is currently not well established. For tumors of epithelial and fibromatous origin collagenase production can enhance the invasive capacity of cells to penetrate basement membranes. We showed previously that a c-Ha-ras transformed glial cell line (CxT24neo3) invaded hamster brain tissue in vivo. These cells were also capable of invading reconstituted basement membrane and embryonic chick hearts in vitro. Since the histopathology of CxT24neo3 tumors mimics that of glioblastoma multiforme in humans, CxT24neo3 was used as the model in vitro for this type of brain tumor. Presently, we detected by zymogram analysis a gelatinase that was secreted by CxT24neo3 and that had an apparent molecular mass of 62 kD. To verify whether gelatinase affected invasion in vitro of these glial cells we determined the efficacy of a substrate specific collagenase inhibitor on invasion in vitro. GM6001 is a synthetic polypeptide that specifically occupies the substrate binding sites of metalloprotease. Since this drug did not show cytotoxicity, its specificity for metalloprotease is a valuable tool to evaluate the physiological function of these enzymes on invasion. We found that treatment of CxT24neo3 with GM6001 reduced the fraction of invading CxT24neo3 cells through reconstituted basement membrane. These data suggest that metalloproteases can stimulate brain tumor invasion.

Decreasing the level of translation initiation factor 4E with antisense RNA causes reversal of ras-mediated transformation and tumorigenesis of cloned rat embryo fibroblasts

Transformation of cloned rat embryo fibroblasts (CREF) with the T24-ras oncogene results in loss of contact inhibition, growth in soft agar and tumor formation in nude mice. Previously we showed that in such cells (CREF T24), the phosphorylation rate of protein synthesis initiation factor 4E (eIF-4E) is increased, correlating with an increase in the general rate of protein synthesis. In the present study, we have expressed antisense RNA complementary to eIF-4E mRNA in CREF T24 cells using a stably integrated vector. Cells expressing antisense RNA (CREF T24/AS) contained 30-50% of the normal level of eIF-4E and exhibited many of the properties of untransformed cells. CREF T24 had a spindle-shaped, refractile appearance, whereas CREF T24/AS grew in ordered, parallel patterns and exhibited contact inhibition similar to untransformed CREF. The rates of growth and protein synthesis in CREF T24/AS were decreased compared to CREF T24 but were not as low as in CREF. The efficiency of growth in soft agar was 11-fold lower for CREF T24/AS compared with CREF T24. The latency period for tumor formation in nude mice was increased from 8 days for CREF T24 to 17-27 days for CREF T24/AS and various clonal lines derived from them. Cell lines established from these CREF T24/AS-derived tumors were shown to have partially regained the eIF-4E levels characteristic of CREF T24. These results demonstrate that many of the phenotypic alterations associated with ras-induced malignant transformation can be reversed by a moderate reduction of the translational initiation capacity and therefore may be mediated through a translational mechanism.

Defining the critical gene expression changes associated with expression and suppression of the tumorigenic and metastatic phenotype in Ha-ras-transformed cloned rat embryo fibroblast cells

Carcinogenesis requires a complex series of genetic changes often involving multiple oncogenes and the inactivation of multiple tumor-suppressor genes. We presently examined the effect of the Krev-1 tumor-suppressor gene on the tumorigenic and metastatic potential of Ha-ras-transformed cloned rat embryo fibroblast (CREF) cells. Ha-ras-transformed CREF cells are morphologically transformed and anchorage independent; produce reduced levels of nm23-H1 (a putative metastasis-suppressor gene product) and TIMP-1 (tissue inhibitor of metalloproteinase 1) transcripts and mRNA compared with CREF cells; produce increased levels of cripto, 94-kDa gelatinase/type IV collagenase (94-kDa GEL), osteopontin (OPN) and transin/stromelysin transcripts and mRNA compared with CREF cells; and are tumorigenic and metastatic in both nude mice and syngeneic rats. Ha-ras-transformed CREF cells coexpressing the Krev-1 gene display a reversion in cellular phenotype and gene expression to that of untransformed CREF cells. However, Ha-ras/Krev-1-coexpressing CREF cells retain, albeit with extended latency periods, both tumorigenic and metastatic potential that is not related directly to the final level of Ha-ras or Krev-1 mRNA or the Ha-ras p21 transforming protein. Development of metastatic potential is, however, directly correlated with a reduction in nm23-H1 and TIMP-1 transcription and mRNA levels and an enhanced expression of cripto, 94-kDa GEL, osteopontin and transin. In contrast, expression of additional tumor-suppressor genes, such as the RB gene and p53, or genes associated with tumorigenesis in other model systems, such as major excreted glycoprotein (MEP), 72-kDa gelatinase/type IV collagenase (72-kDa GEL), fibronectin (FIB), tenascin and intracellular adhesion molecule 1 (ICAM-1) is not altered in a consistent manner during in vitro transformation suppression or escape from tumorigenic and metastatic suppression. These results indicate that Krev-1 suppression of the Ha-ras-transformed/oncogenic phenotype is associated with a distinct program of gene expression changes manifested by altered rates of transcription and steady-state mRNA levels of specific oncogenic-suppressing and oncogenic-inducing genes. These data support a model of Ha-ras-induced metastasis in CREF cells that involves a direct modulation in the expression/suppression of specific combinations of oncogenic-suppressor genes and metastasis-promoting genes that are regulated coordinately in the process of tumor progression.

Wild-type adenovirus type 5 transforming genes function as transdominant suppressors of oncogenesis in mutant adenovirus type 5 transformed rat embryo fibroblast cells

Transformation of cloned rat embryo fibroblast (CREF) cells with the host-range adenovirus type 5 (Ad5) mutant, H5hr1, results in transformants with a fibroblastic morphology which displays a cold-sensitive transformation phenotype and oncogenic potential in both nude mice and syngeneic rats. In contrast, wild-type (wt) Ad5 transformed CREF cells are epithelioid in morphology, temperature independent for transformation, and nontumorigenic. The present studies were conducted to analyze the contribution of the mutated E1A and E1B regions of H5hr1 in regulating the biological properties of H5hr1-transformed CREF cells. CREF cells were constructed which contain the mutated E1A and E1B transforming regions of H5hr1 and either a wt Ad5 E1A gene, a wt Ad5 E1B gene, or both a wt Ad5 E1A and a wt E1B gene. A wt Ad5 E1A gene was sufficient in reversing the cold-sensitive transformation phenotype. By using a wt Ad5 E1A gene under the transcriptional control of a dexamethasone-inducible mouse mammary tumor virus promoter, a direct suppressive effect of wt Ad5 E1A on colony formation in monolayer culture and agar growth of H5hr1-transformed cells was demonstrated. Expression of a wt Ad5 E1A, a wt Ad5 E1B, or both wt transforming genes in H5hr1-transformed CREF cells also suppressed oncogenicity. The ability or inability to form tumors in animals was found not to correlate with sensitivity to natural killer cell-mediated lysis. These results indicate that both the wt Ad5 E1A and wt Ad5 E1B genes can function as dominant suppressors of the oncogenic process when coexpressed in H5hr1-transformed CREF cells. This effect does not require large quantities of wt Ad5 E1A or E1B transforming proteins, nor is it directly related to the acquisition of a natural killer cell cytolysis-susceptible phenotype.

A link between ras and metastatic behavior of tumor cells: ras induces CD44 promoter activity and leads to low-level expression of metastasis-specific variants of CD44 in CREF cells

The activated oncogene c-Ha-ras induces expression of the surface glycoprotein CD44 in cloned rat embryonic fibroblasts (CREF). Induction is transcriptional as shown by transient cotransfections of c-Ha-ras expression constructs and CD44 promoter reporter gene constructs and depends on the presence of an AP-1 binding site at position -110. Increased transcript levels for the standard isoform of CD44 (CD44s) are accompanied by the appearance of alternatively spliced RNAs and the synthesis of variants of CD44 (CD44v). These CD44v molecules differ from the standard type by the addition of sequences in the extracellular portion of the molecules. The occurrence of CD44v molecules in CREF cells upon induction of the CD44 promoter is probably due to leakiness of the splice control in these cells since stable transfection with c-Ha-ras does not alter the CD44v/total CD44 ratio. Upon ras overexpression, however, using an inducible mouse mammary tumor virus-ras construct, a transient increase of CD44v/total CD44 ratio of 3-4 has been determined suggesting that a burst of ras expression, in the genetic background of CREF cells, influences both promoter activity and splice control or accuracy. The expression of CD44v proteins is responsible for the metastatic potential in a variety of tumors (U. Günthert et al., Cell, 65: 13-24, 1991). Also in CREF cells expression of CD44v correlates with metastatic behavior, ras-transfected CREF cells are not only fully transformed but also give rise to metastatic spread as measured in the spontaneous metastasis assay. The adenoviral oncogene E1A counteracts ras-induced promoter function and, consequently, inhibits metastatic behavior without extinguishing transformation.

Induced expression of the endogenous beta interferon gene in adenovirus type 5-transformed rat fibroblasts

Tumorigenesis is a multistep process involving both genetic and epigenetic changes resulting in altered cellular gene expression. While many phenotypic attributes of transformed cells have been described, the cellular genes responsible for these phenotypes are largely unknown. In this study, we show that the interferon-stimulated gene (ISG) ISG15 is expressed in all adenovirus type 5 (Ad5)-transformed rodent cells tested, in an E1A-dependent manner. We find that the level of ISG15 mRNA correlates with the level of the transcription factor ISGF3, which has been postulated to be the transcriptional activator of ISGs. Consistent with the activation of the interferon transduction pathway in Ad5-transformed cells, beta interferon mRNA is expressed in all but the parental untransformed cell line. The level of ISG15 mRNA in Ad5-transformed cells correlated inversely with the ability of these cells to proliferate in soft agar. This appears to have functional significance, since the phenotype of poor growth in agar could be conferred upon a cell line that grows efficiently in soft agar by using conditioned media from cells that grow poorly in soft agar. The same effect could be mimicked by applying rat interferon. We conclude that the degree of activation of the interferon signal transduction pathway explains differences in the transformation phenotypes among Ad5-transformed cell lines.

Transfer of a dominant-acting tumor-inducing oncogene from human prostatic carcinoma cells to cloned rat embryo fibroblast cells by DNA-transfection

The mechanism by which normal human prostate cells develop into prostatic carcinoma cells is not presently known. In the present study we have tested the hypothesis that specific prostatic carcinomas develop as a consequence of activation of a cellular gene(s) with transforming and tumorigenic potential. To test this possibility, high molecular weight DNA was extracted from the human prostatic carcinoma cell line, LNCaP, and cotransfected with a dominant acting neomycin resistance gene, pSV2-neo, into a subclone of Fischer rat embryo fibroblast (CREF) cells, CREF-Trans 6, and NIH-3T3 cells. Cells were selected for growth in G418 and pooled resistant colonies, which were morphologically normal, were injected subcutaneously into athymic nude mice. Tumors developed in several of the animals inoculated with LNCaP DNA-transfected CREF-Trans 6 cells and they were established in monolayer culture. In contrast, no tumors developed in nude mice injected with untransfected CREF-Trans 6 cells, pSV2-neo transfected CREF-Trans 6 cells or LNCaP plus pSV2-neo DNA-transfected NIH-3T3 cells. DNA from the first cycle tumor-derived CREF-Trans 6 cell lines, which were morphologically transformed in monolayer culture, was cotransfected with pSV2-neo a second time into CREF-Trans 6 cells and transfected cells, which were still morphologically normal, were injected into nude mice. Tumors developed in animals and they were again established in tissue culture. Secondary transfectants isolated from animals were morphologically transformed and grew with high efficiency in agar. Both primary and secondary LNCaP-transfected-nude mouse tumor derived-CREF-Trans 6 cells contained human repetitive (Alu) sequences. Although the pattern of Alu integration in the tumor derived CREF-Trans 6 cells were different for different tumors, both primary and secondary tumors contained a single apparently common-sized Alu fragment. The present study indicates that the human prostatic carcinoma cell line, LNCaP, contains a dominant-acting tumor-inducing oncogene which does not induce morphological transformation of CREF-Trans 6 or NIH-3T3 cells in monolayer culture. In addition, the CREF-Trans 6 cell line can detect this tumor-inducing gene function, whereas this activity is not observed in DNA-transfected NIH-3T3 cells.

Induction and progression of the transformed phenotype in cloned rat embryo fibroblast cells: studies employing type 5 adenovirus and wild-type and mutant Ha-ras oncogenes

Transformation of cloned rat embryo fibroblast (CREF) cells with the wild-type 5 adenovirus (wtAd5) transforming genes E1A and E1B (which extend from 0 to 11.2 map units) results in morphologically transformed cells that exhibit an increased saturation density in monolayer culture and display an anchorage-independent phenotype. WtAd5-transformed CREF (wtAd5 CREF) cells do not, however, induce tumors when injected subcutaneously into athymic nude mice or syngeneic Fischer rats. We have analyzed the effect of the ras oncogene and site-specific mutants in the ras oncogene that result in p21 proteins with altered biochemical properties on the oncogenic and metastatic properties of singly (ras) and doubly (ras + wtAd5) transformed CREF cells. Transformants expressing the wild-type ras p21 protein and ras mutants producing p21 proteins that retained GTP-binding properties grew in agar, induced tumors in nude mice and syngeneic rats, and metastasized to the lungs of rats when injected into their tail veins. In contrast, cells transformed with the ras mutant 116K (which contains a mutation at residue 116 that produces a Lys instead of an Asn and does not bind GTP or induce CREF cells to grow in agar) did not become morphologically transformed and were not oncogenic when injected subcutaneously into either nude mice or Fischer rats; further, such cells were not metastatic when injected into the tail veins of Fischer rats. When the wild-type ras or the ras mutants, including 116K, were expressed in nontumorigenic E1A-plus-E1B-expressing wtAd5 CREF cells, transformed cells induced tumors in both types of animals. The CREF cells doubly transformed with 116K + wtAd5, unlike transformants containing the wild-type ras and the other ras mutants that still retained GTP binding, were still unable to induce lung metastases. In addition, 116K + wtAd5-transformed CREF cells also did not display any alterations in morphology distinguishable from wtAd5 CREF cells and were not able to grow in agar with increased efficiency. These results indicate that the loss of GTP-binding ability by this mutant p21 ras protein eliminated the ability of these proteins to induce an oncogenic phenotype in an immortal but normal CREF cell line. However, the mutant ras could cooperate with wtAd5 transforming genes in transformed CREF cells to make these cells progress to an oncogenic (but not metastatic) phenotype.

Cytokinesis is more rapid in Ha-T24-ras transfected rat embryo fibroblasts than in non-transfected control cells

It has long been known that neoplastic cells are characterized by increases in cell motility. Earlier studies from this laboratory indicated that mitotic events were also altered in many tumor and experimentally transformed cells and that this included increases in metaphase duration and a reduction in the duration of cytokinesis. The studies presented in this paper were done to determine whether or not transfection of normal rat embryo fibroblasts by the Ha-T24-ras oncogene could also produce such alterations in mitotic events. The results obtained with the use of time lapse video microscopy indicate that neither the duration of metaphase nor the rate of chromosome movement during anaphase was altered but that the rate of furrow progression during cytokinesis occurred at a significantly more rapid rate. Thus, the cellular alterations induced by transfection with Ha-T24-ras accelerate microfilament-dependent cytokinetic furrowing without significant effects on microtubule-dependent mitotic events. One of several possible mechanisms that could account for these observations involves a down regulation of protein kinase C which has been reported to occur in many neoplastic cells including those transformed by ras. Such a hypothesis could also have broader implications because it may be applicable to the increase in motility and metastatic activity generally observed in transformed cells.

Changes in NF-kappa B and ISGF3 DNA binding activities are responsible for differences in MHC and beta-IFN gene expression in Ad5- versus Ad12-transformed cells

Changes in MHC class I expression are frequently observed in tumors, which represents at least one mechanism by which tumor cells escape immune surveillance. MHC class I expression is often suppressed in type 12 adenovirus (Ad12)-transformed rodent cells, but is highly induced in Ad5-transformed cells. This difference helps to explain why Ad12 but not Ad5 can induce tumors in immunocompetent syngeneic rats. In this report we demonstrate that only Ad5- but not Ad12-transformed rodent fibroblasts constitutively express beta-IFN which results in ISGF3 factor induction, and stimulation of MHC class I expression. Furthermore, we demonstrate that in contrast to Ad12-transformed cells, Ad5-transformed cells show constitutive levels of nuclear NF-kappa B-like DNA binding activity. This is of particular interest since both the beta-IFN and the MHC class I promoters contain an NF-kappa B DNA binding site. Thus, high levels of MHC class I expression in Ad5-transformed cells are due to a combinatorial stimulation of two cis-regulatory sequences of the MHC class I promoter: the NF-kappa B binding site and the interferon stimulated response element (ISRE), which binds the ISGF3 factor complex. The failure of Ad12-transformed cells to activate this pathway explains their low levels of MHC class I expression and their greater oncogenicity.

The influence of the presence of adenovirus 5 E1a and E1b sequences on the pathology of rat embryonic fibroblasts transfected with activated c-Ha-ras and v-ras

We compared the pathology of two groups of tumors following implantation of cells enmeshed in alginate beads into the syngeneic rat. The first group of tumors was generated by implanting alginate beads containing cloned embryonic fibroblasts (CREF) that were transfected with activated c-Ha-ras (T24) and v-ras (pH1) (CREF tumors). The second group was created by implantation of CREF cells that were transfected with E1a and E1b of wild type adenovirus type 5 prior to transfection with T24 and pH1 (Wt tumors). Alginate beads were implanted at three different sites in the rat, i.e. subcutaneous in the flank, subcutaneous in the tail and under the renal capsule. Tumorigenicity, invasiveness and metastatic capacity of the transfectant cell lines were determined. The tumor latency period (TLP), the doubling time of the tumors and the metastatic capacity of the cell lines depended on the site of implantation. Invasion was not influenced by site-dependency. Wt tumors were invasive and generally had longer TLP than the CREF tumors. Wt tumors did not metastasize to the lungs as opposed to CREF tumors. We concluded that the genetic background of Wt cells modulated the effect of ras transfection by stretching the TLP and by limiting the metastatic potential to the draining lymph nodes. Malignancy per se was not repressed since no differences in invasive capacity were noticed.

The effect of dibutyryl camp (dBcAMP) on morphological differentiation, growth and invasion in vitro of a hamster brain-tumor cell line: a comparative study of dBcAMP effects in 2- and 3-dimensional cultures

The use of agents that stimulate cancer cells to differentiate is proposed as a potential approach to the treatment of malignancy. To evaluate the effects of a differentiation inducer on morphology, growth and invasion in vitro of brain-tumor cells, a diffusely invasive hamster glial cell line (CxT3C15) was treated with ImM dibutyryl cyclic adenosine monophosphate (dBcAMP). The efficacy of dBcAMP was tested in monolayer cultures, 3-dimensional static cultures (i.e., spheroids) and confrontation cultures with an embryonic chick heart. CxT3C15 cells exhibited increased numbers of long cellular processes (morphological differentiation) following treatment of monolayer cultures with ImM dBcAMP. One mM dBcAMP also altered the macroscopic and ultrastructural morphology of CxT3C15 grown as spheroids. These alterations were: (i) a fast transition of rough to smooth morphology macroscopically, and (ii) fading of the cell borders concomitant with the disappearance of cell-membrane excrescences, as seen by scanning electron microscopy. Exponential growth of CxT3C15 in monolayers was not changed following treatment with ImM dBcAMP. Treatment of CxT3C15 spheroids with the same dose of dBcAMP caused a reduction of relative volume increase (30-40%). Invasion of CxT3C15 in an embryonic chick heart in vitro was not altered after addition (prior to or at the time of co-culture) of ImM dBcAMP to the co-cultures. These results indicate that invasion of CxT3C15 is not necessarily linked to morphological differentiation or moderated by reduced proliferation.

Alterations in SV40 DNA integration patterns are associated with acquisition of the invasive phenotype in hamster brain tumors

A panel of cell lines that represents a reproducible, easily manipulated experimental system which discriminates between the minimally and diffusely invasive phenotypes of brain tumors has been developed. A population of SV40-transformed glial cells derived from newborn hamster cerebral cortex (Cx) has been sequentially passaged in newborn hamsters by intracerebral inoculation followed by in vitro culture, and after each passage progressively more invasive cell lines have been established. To study the molecular basis for the observed phenotypic characteristics associated with invasiveness, cloned cells were isolated from the first (Cx4T1-derived) and third Passage (Cx4T3-derived) cells lines. After injection into hamster brain, these cloned cells produce tumors that were either minimally invasive (Cx4T1-derived) or diffusely invasive (Cx4T3-derived) into normal brain tissue. In our initial attempt to identify and characterize the cellular and molecular factors that modulate the invasive phenotype, restriction endonuclease generated SV40 DNA-containing fragment patterns of DNA from each parental cell line and each of the clonal variants were determined by Southern transfer-hybridization. The results suggest the cell lines are composed of a limited number of tumorigenic subpopulations, each of which contain characteristic arrangements of integrated SV40 DNA with repeated in vivo/in vitro passage the avvangement of intecyvated SV40 changed. Analysis of DNA from minimally and diffusely invasive cloned cells indicated strong similarities of integrated SV40 DNA arrangement to their parental cells with the greatest similarities in cells exhibiting comparable invasive phenotypes. A striking difference was seen, however, in comparisons of SV40 DNA-containing fragment patterns of DNA extracted from clones which induced marginally versus diffusely invasive tumors. These differences suggest that the invasive cells were selected from a distinct minority subpopulation or that they may have arisen as a consequence of a more dynamic process of genetic rearrangement. This cell system appears to mimic the phenotypic and genetic heterogeneity observed in human tumors of glial origin and should prove valuable in defining the biochemical and molecular basis of tumor cell invasion.

Role of the Ha-ras (RasH) oncogene in mediating progression of the tumor cell phenotype (review)

Recent experimental evidence indicates that the c-Ha-ras (rasH) oncogene may be causally involved in the etiology and evolution of specific human neoplasms. In addition, cultured cells transformed by the rasH oncogene can induce both a tumorigenic and a metastatic phenotype when expressed in appropriate cultured cells. To begin to define the molecular and biochemical mechanism(s) by which the rasH oncogene induce their effects on expression of the transformed state we have employed a cloned rat embryo fibroblast (CREF) cell line. Transformation of CREF cells with wild-type 5 adenovirus (Wt) results in transformed cells which display anchorage-independence and an increased saturation density in monolayer culture, but are non-tumorigenic in both athymic nude mice and syngeneic Fischer rats. In contrast, when CREF cells are transformed with mutant type 5 adenoviruses, such as H5hrl, or the ElA transforming gene from hrl (0-4.5), tumors are induced in both nude mice and syngeneic rats. However, hrl (0-4.5)-transformed CREF cells are not metastatic following intravenous injection into the tail vein of syngeneic rats. Insertion of an activated T24 rasH oncogene or a wild-type v-rasH oncogene into CREF, wt-transformed CREF or hrl (0-4.5)-transformed CREF cells results in acquisition of a metastatic phenotype by these cells. A mutant v-rasH oncogene (mutant 116K), which is defective in GTP binding and the induction of transformation of NIH 3T3 cells, does not induce transformation in CREF cells, but it can progress wt-transformed CREF cells to a tumorigenic-non-metastatic state. Employing this model system which displays well-defined and stable stages in the tumor cell progression lineage, we have analyzed the potential role of changes in the phosphatidylinositol (PI) cycle and phospholipase A2 (PLA2) enzyme activity during progression to a tumorigenic and metastatic phenotype. An increase in PI cycle intermediates (primarily inositol triphosphate; IP3) were observed only in the wt-transformed and hrl (0-4.5)-transformed CREF cell lines transfected with the rasH oncogene. In the case of PLA2, all rasH-transformed CREF cell lines displayed increased activity. In contrast, CREF cells transformed only by Ad5 (Wt or hrl (0-4.5)) or the 116K v-rasH oncogene did not display increased PLA2 activity similar to that observed in rasH transfected cells. Since one important metabolite generated by PLA2 is arachidonic acid, which is converted into prostaglandins and leukotrienes by cyclooxygenase or lipooxygenase, respectively, the levels of prostaglandin E2 (PGE2) in the various cell lines were monitored.(ABSTRACT TRUNCATED AT 400 WORDS)

Effect of methyl methanesulfonate on type 5 adenovirus DNA integration and the phenotypic properties of cold-sensitive type 5 adenovirus-transformed cloned rat embryo fibroblast cells

Pretreatment of a cloned rat embryo fibroblast cell line (CREF) with methyl methanesulfonate (MMS) prior to infection with a specific cold-sensitive type 5 adenovirus mutant, H5hr1, results in a unique carcinogen enhancement of transformation phenotype. MMS induces a dose-dependent increase in the absolute number of transformed foci in comparison with solvent-treated controls as well as an increase in transformation frequency when normalized for carcinogen-induced cell toxicity. To determine if the carcinogen enhancement of transformation phenotype was a consequence of the carcinogen altering the pattern of type 5 adenovirus (Ad5) DNA integration into the genome of CREF cells and/or if carcinogen treatment modified the phenotype of established H5hr1-transformed CREF cells, we have analyzed a series of single cell-derived H5hr1-transformed CREF cultures which were isolated from cultures pretreated with carcinogen-solvent or MMS prior to infection with H5hr1. Analysis of viral DNA integration by DNA filter-transfer hybridization (Southern blotting) indicated that MMS pretreatment did not increase the copy number of Ad5 DNA sequences which persisted in H5hr1-transformed clones or result in transformants which contained identical DNA restriction enzyme cleavage patterns. MMS-pretreated H5hr1-transformed clones also did not differ significantly from solvent-pretreated H5hr1-transformed clones in their ability to grow in agar, bind 125I-epidermal growth factor, or form tumors in athymic nude mice. MMS-pretreated H5hr1-transformed CREF clones retained a similar cold-sensitive negative regulation in the expression of the transformed cell phenotype as did H5hr1-transformed clones not exposed to carcinogens. These findings suggest that the unique carcinogen enhancement of transformation phenotype displayed by CREF cells pretreated with MMS prior to infection with H5hr1 does not result in transformants which either contain increased concentrations of Ad5 DNA or similar patterns of Ad5 DNA integration. Furthermore, carcinogen-pretreated H5hr1 transformants did not display novel phenotypes not expressed by cloned H5hr1-transformed CREF cell lines exposed to solvent prior to viral infection.

Transfection of mammalian cells with plasmid DNA by scrape loading and sonication loading

Scrape loading and sonication loading are two recently described methods of introducing macromolecules into living cells. We have tested the efficacy of these methods for transfection of mammalian cells with exogenous DNA, using selection systems based either on resistance to the drug G418 (Geneticin) or on acquisition of the ability to utilize the salvage pathway of pyrimidine biosynthesis. These loading methods can be employed to generate cell lines that express the gene product of the transfected DNA molecules both transiently and stably. Optimal transfection is observed when the DNA is added to cells in physiological saline lacking divalent cations and containing K+ in place of Na+. DNA molecules 7.1 to 30 kilobases long have been introduced by the scrape loading procedure. In addition, the scrape loading procedure has been employed for cotransfection and subsequent expression of nonselectable genes encoded on DNA molecules added in a mixture with DNA molecules whose expression is selected. Cell lines expressing oncogenes or proteins that are important for regulation of cell growth and division have been obtained by this procedure. The scrape loading procedure is also useful for studies of the cellular changes that occur upon expression of an exogenous gene. As many as 80% of cells scrape loaded with the plasmid pC6, which encodes the simian virus 40 large tumor antigen, contained this protein in the nucleus between 1 and 5 days after transfection. Thus, scrape loading and sonication loading are simple, economical, and reproducible methods for introduction of DNA molecules into adherent and nonadherent cells, and these methods may be useful in the future for experimentation at both fundamental and applied levels.

Invasiveness in primary intracranial tumors: Part 2. Studies with scanning electron microscopy of cell surface alterations associated with invasiveness

We previously described an experimental model for the production of invasive and noninvasive astrocytic series tumors and a semiquantitative assessment of their invasiveness. The tumors are produced by intracerebral inoculation of simian virus 40-transformed cells from four different brain regions. Cells of cerebral cortex and brain stem derivation produced invasive tumors; tumors of cerebral cortex derivation were more invasive and became increasingly invasive with alternate in vivo and in vitro passage. Cells of cerebellar hemisphere and vermis derivation produced primarily noninvasive tumors. This report describes the surface configuration of these tumor cells in culture at or near confluence as visualized with scanning electron microscopy. Normal cells form a multilayered base of flat, overlapping cells with few excrescences and indistinct borders and have only rare dividing or giant cells attached. Invasive tumor cells from a monolayer base of extremely flat and spread out cells almost devoid of excrescences, with few dividing or giant cells attached. Cells of cerebral cortex derivation additionally have numerous microvilli and ruffles at points of intercellular contact and become covered with microvilli after passage. These features were retained after cloning by dilution plating, but not after cloning by growth in soft agar. Our primarily noninvasive cells form a multilayered base of rounded cells covered with various excrescences and numerous attached dividing and giant cells. These surface features seem to be related to intercellular and cell-substrate adherence. The configuration of the invasive cells is consistent with increased cell-substrate adherence, substrate-dependent inhibition of locomotion, and decreased intercellular adherence among the more invasive cells. The configuration of our primarily noninvasive cells is consistent with decreased cell-substrate adherence and unrestricted multilayered growth. Thus, it seems that invasiveness is expressed at the cell surface and is related to disturbances in adherence balance rather than in cell proliferation.

Mutations in the E1a gene of type 5 adenovirus result in oncogenic transformation of Fischer rat embryo cells

Transformation of a specific clone of Fischer rat embryo (CREF) cells with wild-type 5 adenovirus (Ad5) or the E1a plus E1b transforming gene regions of Ad5 results in epithelioid transformants that grow efficiently in agar but that do not induce tumors when inoculated into nude mice or syngeneic Fischer rats. In contrast, CREF cells transformed by a host-range Ad5 mutant, H5hrl, which contains a single base-pair deletion of nucleotide 1055 in E1a resulting in a 28-kd protein (calculated) in place of the wild-type 51-kd acidic protein, display a cold-sensitive transformation phenotype and an incomplete fibroblastic morphology but surprisingly do induce tumors in nude mice and syngeneic rats. Tumors develop in both types of animals following injection of CREF cells transformed by other cold-sensitive Ad5 E1a mutants (H5dl101 and H5in106), which contain alterations in their 13S mRNA and consequently truncated 289AA proteins. CREF cells transformed with only the E1a gene (0-4.5 m.u.) from H5hrl or H5dl101 also produce tumors in these animals. To directly determine the role of the 13S E1a encoded 289AA protein and the 12S E1a encoded 243AA protein in initiating an oncogenic phenotype in adenovirus-transformed CREF cells, we generated transformed cell lines following infection with the Ad2 mutant pm975, which synthesizes the 289AA E1a protein but not the 243AA protein, and the Ad5 mutant H5dl520 and the Ad2 mutant H2dl1500, which do not produce the 289AA E1a protein but synthesize the normal 243AA E1a protein. All three types of mutant adenovirus-transformed CREF cells induced tumors in nude mice and syngeneic rats. Tumor formation by these mutant adenovirus-transformed CREF cells was not associated with changes in the arrangement of integrated adenovirus DNA or in the expression of adenovirus early genes. These results indicate, therefore, that oncogenic transformation of CREF cells can occur in the presence of a wild-type 13S E1a protein or a wild-type 12S E1a protein when either protein is present alone, but does not occur when both wild-type E1a proteins are present.

Invasiveness in primary intracranial tumors: Part 1. An experimental model using cloned SV40 virus-produced hamster brain tumors

This report presents an experimental model for study of the cellular and molecular biology of invasiveness in tumors. It uses SV40 virus for the production of primary intracranial tumors that are invasive for normal brain and vary markedly and predictably in this invasiveness. Cell cultures of dissociated 1- to 2-day-old Syrian hamster cerebral cortex (Cx), brain stem (Bs), cerebellar hemisphere (Cbh), and cerebellar vermis (Cbv) were transformed with SV40 virus and inoculated intracerebrally into newborn hamsters. All 368 animals that developed intracranial tumors were killed, and tumor was taken for histological and immunofluorescence studies, assessment of extent of invasiveness, and preparation of cell cultures from which cells were cloned by dilution plating or growth in soft agar. A few hamsters were perfused with glutaraldehyde for studies of tumor ultrastructure. All cloned and uncloned tumor cells were reinoculated to produce second- and third-passage tumors. Characteristic differences in morphology and growth rate were observed between normal astrocytes derived from each brain region, and these phenotypic differences were retained after virus transformation and tumor production. Cloned and uncloned Cx cell-derived tumors of second and third passage diffusely invaded adjacent normal brain, although those of first passage invaded only slightly. Except for extracerebral spread, these tumors resembled human astrocytic series tumors. Bs and some Cbh cell-derived tumors were also astrocytic but more undifferentiated and only slightly invasive; Cbv and other Cbh cell-derived tumors were sarcomatous and only extended along perivascular spaces or were not invasive at all. The tumor cells contained glial fibrillary acidic protein and SV40 T-antigen. These results suggest that astrocytes from different brain regions vary in genomic stability and support the theory that differences in invasiveness reflect the development of heterogeneity and subsequent selection of more aggressive subpopulations of cells.

Mutations in the E1a gene of adenovirus type 5 alter the tumorigenic properties of transformed cloned rat embryo fibroblast cells

The adenovirus type 5 mutants H5hr1 and H5dl101 contain modifications in the E1a gene affecting the 13S mRNA-encoded 289-amino acid polypeptide and exhibit a cold-sensitive transformation phenotype upon infection of cloned rat embryo fibroblast (CREF) cells. Transformed cell lines expressing solely E1a or E1a and E1b gene products derived from these viruses display enhanced anchorage-independent growth at 37 degrees C versus 32 degrees C and display a cytoskeletal architecture resembling untransformed fibroblastic CREF cells. In contrast, CREF cells transformed by H5wt or the E1a and E1b region of H5wt grow with similar efficiency in agar at 37 degrees C or 32 degrees C and exhibit an epithelioid morphology that is associated with an altered cytoskeleton. Regardless of the expression or presence of other viral early regions, including E1b, E2a, and E4 genes, specific CREF cell lines expressing an altered 289-amino acid protein and a wild-type 12S mRNA-encoded 243-amino acid protein were capable of inducing tumors in nude mice and in immunocompetent syngeneic Fischer rats. In sharp contrast, cells expressing a wild-type 289-amino acid protein were unable to induce tumors in either nude mice or syngeneic rats. The ability to induce tumors did not correlate with alterations in the pattern of viral DNA integration or differential expression of the E1a and E1b genes, nor was the tumor induction a consequence of unique properties of the immortal parental CREF cell line.

Reversibility of progression of the transformed phenotype in Ad5-transformed rat embryo cells

The carcinogenic process is extremely complex and is affected by diverse environmental and host factors. The mechanism for the gradual development of the transformed phenotype (a process termed "progression") was studied in type 5 adenovirus (Ad5)-transformed rat embryo cells. Progression was not correlated with major changes in the pattern of integration of viral DNA sequences. Instead, it was associated with an increased methylation of integrated viral sequences other than those corresponding to the E1 transforming genes of Ad5. A single exposure of progressed cells to the demethylating agent 5-azacytidine (Aza) resulted in a stable reversion to the unprogressed state of the original parental clone. A further selection of cells after growth in agar allowed the isolation of Aza-treated clones that had regained the progressed phenotype. These observations indicate that progression is a reversible process and suggest that progression may be associated with changes in the state of methylation of one or more specific genes.

Cytogenetic characterization and DNA content analysis of Ad 2-transformed rat embryo brain cells

An adenovirus type 2-transformed rat embryo brain cell line (F 17 A2AS) and two of its subclones (F 17 CI, F 17 C2) have been studied using chromosome banding and flow cytometric techniques. In determining the modal chromosome number, a bimodal distribution was observed in each of the cell lines. In each case the first numerical mode fell in the hypertriploid or hypotetraploid range while the second represented a mode in the hypertetraploid range. Analysis of Giemsa-banded karyotypes revealed the presence of several marker chromosomes. In most cases the origins of the markers could be established from their characteristics Giemsa-banding patterns. In particular, chromosome 2 was involved in the formation of several marker chromosomes. The DNA content analysis confirmed the bimodal chromosome distribution with values in the near tetraploid and near pentaploid range for each cell line.

Mechanisms of cisplatin (cis-diamminodichloroplatinum II)-induced cytotoxicity and genotoxicity in yeast

The antitumor drug, cisplatin (cis- diamminodichloroplatinum II), dissolved in both water and phosphate-buffered saline, was studied for its genotoxic and cytotoxic effects in the yeast, Saccharomyces cerevisiae. The results showed that the drug was both recombinagenic and mutagenic in the wild-type diploid strain D7. It was observed that both cytotoxicity and genotoxicity were greatly reduced when cisplatin was dissolved in phosphate-buffered saline compared to the aqueous solution. Cell survival analyses showed that the diploid strain (D7 rad 3), deficient in excision of UV-induced pyrimidine dimers or similar adducts, was hypersensitive to cisplatin. Another diploid strain (rad 52/rad 52), blocked in the repair of DNA double-strand breaks and recombination was also hypersensitive to the drug. Mitotic gene conversion was not observed in the rad 52/rad 52 diploid after the drug treatments, while it was reduced in the excision -deficient strain. Reverse mutations occurred in the excision-deficient strain (D7 rad 3), even at low doses of cisplatin. These results are discussed in relation to the possible mechanisms of cisplatin-induced cell death and genotoxicity.

Susceptibility of Adenovirus 2-transformed rat cell lines to natural killer (NK) cells: direct correlation between NK resistance and in vivo tumorigenesis

The susceptibility to natural killer (NK)-mediated cell lysis of Adenovirus type 2 (Ad2)-transformed rat embryo fibroblast cell lines, which differed markedly in tumorigenic potential in vivo (T2C4 greater than F19 greater than F17), was investigated by using NK effector cells from F344 rat or athymic nude rat spleens. A comparison of the degree of NK-mediated lysis obtained with these tumor cell targets suggested a direct relationship between the resistance of a cell to NK cell lysis and its potential to form tumors in vivo. The cells were lysed in the following order of increasing susceptibility: T2C4 less than F4 less than F19 less than F17. Whether T cells or macrophages played a significant role in the observed lytic activity was determined by treating the NK effector cell population with anti-rat T cell serum (alpha T) and complement or by depletion of macrophages after binding to a glass bead column and treatment with carbonyl iron. A series of clonal sublines derived from the parental F17 and F4 cell lines further strengthened this relationship between tumorigenesis and resistance to NK-mediated cell lysis. Tumorigenic subclones from the non-tumorigenic F17 parental cells were demonstrated to be comparatively resistant to NK-mediated lysis. Tumorigenic subclones from tumorigenic F4 parental cell population showed a susceptibility to NK-mediated cell lysis virtually identical to the parental F4 cells. The implication of these results are discussed.

Susceptibility of Adenovirus 2-transformed rat cell lines to natural killer (NK) cells: direct correlation between NK resistance and in vivo tumorigenesis

The susceptibility to natural killer (NK)-mediated cell lysis of Adenovirus type 2 (Ad2)-transformed rat embryo fibroblast cell lines, which differed markedly in tumorigenic potential in vivo (T2C4 greater than F19 greater than F17), was investigated by using NK effector cells from F344 rat or athymic nude rat spleens. A comparison of the degree of NK-mediated lysis obtained with these tumor cell targets suggested a direct relationship between the resistance of a cell to NK cell lysis and its potential to form tumors in vivo. The cells were lysed in the following order of increasing susceptibility: T2C4 less than F4 less than F19 less than F17. Whether T cells or macrophages played a significant role in the observed lytic activity was determined by treating the NK effector cell population with anti-rat T cell serum (alpha T) and complement or by depletion of macrophages after binding to a glass bead column and treatment with carbonyl iron. A series of clonal sublines derived from the parental F17 and F4 cell lines further strengthened this relationship between tumorigenesis and resistance to NK-mediated cell lysis. Tumorigenic subclones from the non-tumorigenic F17 parental cells were demonstrated to be comparatively resistant to NK-mediated lysis. Tumorigenic subclones from tumorigenic F4 parental cell population showed a susceptibility to NK-mediated cell lysis virtually identical to the parental F4 cells. The implication of these results are discussed.

Analysis of lectin receptors on rat embryo fibroblasts transformed by adenovirus 2

Transformation of rat embryo fibroblasts by human adenovirus type 2 (Ad2) results in the production of a series of cell lines that cover a spectrum of malignancy from nontumorigenic to highly tumorigenic in a single species. A panel of plant lectins was used to study surface characteristics of these cell lines that might correlate with tumorigenicity. Because of the complex nature of lectin-cell surface interactions, a number of parameters were determined; they included numbers and densities of lectin receptors, binding affinities, and receptor mobilities. The lectins from Lens culinaris, Lotus tetragonolobus, and Ricinus communis were found to be the most useful for differentiating among the various Ad2-transformed cell lines. In general, the more tumorigenic cell lines were characterized by high numbers of lectin receptors, high percentages of lectin-binding cells, and heterogeneous distributions of receptors from cell to cell. In contrast, the nontumorigenic and the weakly tumorigenic cell lines were characterized by low numbers of lectin receptors present on a minority of cells within each population and a more homogeneous distribution of these receptors from cell to cell. These data demonstrate that lectins can identify surface properties that appear to correlate with malignant potential in the Ad2-transformed cell lines.

SV-40 virus-induced neoplastic transformation of hamster brain cells in vitro. Studies with scanning and transmission electron microscopy

Neoplastic transformation of one-day-old hamster brain cells was produced by infection with SV-40 virus and verified by phase contrast microscopy, growth in semisolid media, and intracranial tumor production after inoculation of the cells into other one-day-old hamsters. Transformed cells were studied by transmission and scanning electron microscopy. The numerous alterations in cell surface structure and in nuclear and cytoplasmic organization suggest a marked increase in cell metabolism and in the rate of mitosis and cell division. Cilia with a nine-to-zero pattern of microtubule doublets were present in cells with intermediate size filaments which stained for glial fibrillary acidic protein. The findings indicate that infection of one-day-old hamster brain cells in culture by SV-40 virus results in their transformation to a neoplastic state and the transformed cells are differentiating neoplastic astrocytes.

Role of viruses in the induction of primary intracranial tumors

The role of viruses in the induction of primary intracranial tumors is reviewed. Papovaviruses of the simian virus 40 (SV40) group are used as a representative model, and a distillation of the literature on virus induction of intracranial tumors in laboratory animals and neoplastic transformation of cells in culture is presented. The molecular sequence of events during tumor induction and neoplastic cell transformation is also discussed. Recent evidence that the papovaviruses play a role in the formation of human brain tumors is summarized.

Pyrrol[1,4]benzodiazepine antibiotics. Proposed structures and characteristics of the in vitro deoxyribonucleic acid adducts of anthramycin, tomaymycin, sibiromycin, and neothramycins A and B

The pyrrol[1,4]benzodiazepine antibiotics anthramycin, tomaymycin, sibiromycin, and neothramycins A and B are potent antitumor agents that bind to DNA in a unique manner, resulting in some unusual biological consequences. This paper describes results on which the points of covalent linkage between the drugs (carbinolamine carbon atom) and DNA (N-2 of guanine) are deduced, as well as Corey-Pauling-Koltun (CPK) models for the various drug-DNA adducts. Predictions based upon these CPK models have been tested, and the results are reported in this paper. These tested experimental predictions include (1) instability of the drug-DNA adducts to denaturation of DNA, (2) saturation binding limits, (3) effect of drug binding on the structure of DNA, (4) lack of unwinding and in vitro strand breakage of closed-circular supercoiled simian virus 40 (SV-40) DNA, (5) sensitivity of the secondary structure of DNA to drug binding, (6) hydrodynamic properties of the drug-DNA adducts, (7) hydrogen bonding of the 9-phenolic proton in anthramycin to DNA, (8) structure-activity relationships, and (9) biological consequences of DNA damage, including cumulative damage and slow excision repair, double-strain breaks in DNA in repair-proficient cells, and the selective inhibition of H-strand DNA synthesis in mitochondria. The results are completely in accord with our postulated space-filling models.