Identification of a role for the sialomucin CD164 in myogenic differentiation by signal sequence trapping in yeast.

Determination and differentiation of skeletal muscle precursors requires cell-cell contact, but the full range of cell surface proteins that mediate this requirement and the mechanisms by which they work are not known. To identify participants in cell contact-mediated regulation of myogenesis, genes that encode secreted proteins specifically upregulated during differentiation of C2C12 myoblasts were identified by the yeast signal sequence trap method (K. A. Jacobs, L. A. Collins-Racie, M. Colbert, M. Duckett, M. Golden-Fleet, K. Kelleher, R. Kriz, E. R. La Vallie, D. Merberg, V. Spaulding, J. Stover, M. J. Williamson, and J. M. McCoy, Gene 198:289-296, 1997), followed by RNA expression analysis. We report here the identification of CD164 as a gene expressed in proliferating C2C12 cells that is upregulated during differentiation. CD164 encodes a widely expressed cell surface sialomucin that has been implicated in regulation of cell proliferation and adhesion during hematopoiesis. Stable overexpression of CD164 in C2C12 and F3 myoblasts enhanced their differentiation, as assessed by both morphological and biochemical criteria. Furthermore, expression of antisense CD164 or soluble extracellular regions of CD164 inhibited myogenic differentiation. Treatment of C2C12 cells with sialidase or O-sialoglycoprotease, two enzymes previously reported to destroy functional epitopes on CD164, also inhibited differentiation. These data indicate that (i) CD164 may play a rate-limiting role in differentiation of cultured myoblasts, (ii) sialomucins represent a class of potential effectors of cell contact-mediated regulation of myogenesis, and (iii) carbohydrate-based cell recognition may play a role in mediating this phenomenon.

Developmental expression pattern of the cdo gene.

CDO is a cell-surface protein of the immunoglobulin/fibronectin type III repeat family that positively regulates myogenic differentiation in vitro. To gain a better understanding of the role of cdo during vertebrate development, we carried out an extensive in situ hybridization study to characterize its expression pattern from postimplantation to late stages of mouse embryogenesis and in rat brain from E13 to adult. Our results show a broad pattern of cdo expression that is spatially and temporally restricted during embryogenesis. In the central nervous system (CNS), cdo expression is detected as early as E7.5 and maintained in the dorsal ventricular zones of the brain and spinal cord, becoming increasingly restricted in the adult. High levels of cdo are detected in developing sensory organs, such as the eye and ear. Outside the CNS, cdo is expressed mainly in neural crest and mesodermal derivatives, including skeletal muscle precursors. Overall, the highest levels of cdo expression are seen from E9.0 to E15.5. The temporal onset and restricted expression of cdo suggest that cdo plays a role in the determination and/or differentiation of a number of cell types during embryogenesis.

CDO, a robo-related cell surface protein that mediates myogenic differentiation.

CDO, a member of the Ig/fibronectin type III repeat subfamily of transmembrane proteins that includes the axon guidance receptor Robo, was identified by virtue of its down-regulation by the ras oncogene. We report here that one prominent site of cdo mRNA expression during murine embryogenesis is the early myogenic compartment (newly formed somites, dermomyotome and myotome). CDO is expressed in proliferating and differentiating C2C12 myoblasts and in myoblast lines derived by treating 10T1/2 fibroblasts with 5-azacytidine, but not in parental 10T1/2 cells. Overexpression of CDO in C2C12 cells accelerates differentiation, while expression of secreted soluble extracellular regions of CDO inhibits this process. Oncogenic Ras is known to block differentiation of C2C12 cells via downregulation of MyoD. Reexpression of CDO in C2C12/Ras cells induces MyoD; conversely, MyoD induces CDO. Reexpression of either CDO or MyoD rescues differentiation of C2C12/Ras cells without altering anchorage-independent growth or morphological transformation. CDO and MyoD are therefore involved in a positive feedback loop that is central to the inverse relationship between cell differentiation and transformation. It is proposed that CDO mediates, at least in part, the effects of cell-cell interactions between muscle precursors that are critical in myogenesis.

Ras signals to the cell cycle machinery via multiple pathways to induce anchorage-independent growth.

Several specific cell cycle activities are dependent on cell-substratum adhesion in nontransformed cells, and the ability of the Ras oncoprotein to induce anchorage-independent growth is linked to its ability to abrogate this adhesion requirement. Ras signals via multiple downstream effector proteins, a synergistic combination of which may be required for the highly altered phenotype of fully transformed cells. We describe here studies on cell cycle regulation of anchorage-independent growth that utilize Ras effector loop mutants in NIH 3T3 and Rat 6 cells. Stable expression of activated H-Ras (12V) induced soft agar colony formation by both cell types, but each of three effector loop mutants (12V,35S, 12V,37G, and 12V,40C) was defective in producing this response. Expression of all three possible pairwise combinations of these mutants synergized to induce anchorage-independent growth of NIH 3T3 cells, but only the 12V,35S-12V,37G and 12V,37G-12V,40C combinations were complementary in Rat 6 cells. Each individual effector loop mutant partially relieved adhesion dependence of pRB phosphorylation, cyclin E-dependent kinase activity, and expression of cyclin A in NIH 3T3, but not Rat 6, cells. The pairwise combinations of effector loop mutants that were synergistic in producing anchorage-independent growth in Rat 6 cells also led to synergistic abrogation of the adhesion requirement for these cell cycle activities. The relationship between complementation in producing anchorage-independent growth and enhancement of cell cycle activities was not as clear in NIH 3T3 cells that expressed pairs of mutants, implying the existence of either thresholds for these activities or additional requirements in the induction of anchorage-independent growth. Ectopic expression of cyclin D1, E, or A synergized with individual effector loop mutants to induce soft agar colony formation in NIH 3T3 cells, cyclin A being particularly effective. Taken together, these data indicate that Ras utilizes multiple pathways to signal to the cell cycle machinery and that these pathways synergize to supplant the adhesion requirements of specific cell cycle events, leading to anchorage-independent growth.

CDO: an oncogene-, serum-, and anchorage-regulated member of the Ig/fibronectin type III repeat family.

Cell adhesion molecules of the Ig superfamily are implicated in a wide variety of biological processes, including cell migration, axon guidance and fasciculation, and growth control and tumorigenesis. Expression of these proteins can be highly dynamic and cell type specific, but little is known of the signals that regulate such specificity. Reported here is the molecular cloning and characterization of rat CDO, a novel cell surface glycoprotein of the Ig superfamily that contains five Ig-like repeats, followed by three fibronectin type III-like repeats in its extracellular region, and a 256-amino acid intracellular region that does not resemble other known proteins. In rat embryo fibroblasts, cdo mRNA expression is maximal in confluent, quiescent cells. It is rapidly and transiently down-regulated by serum stimulation of such cells, and is constitutively down-regulated in oncogene-transformed derivatives of these cells. CDO protein levels are also dramatically regulated by cell-substratum adhesion, via a mechanism that is independent of cdo mRNA expression. The amount of CDO produced at the surface of a cell may therefore be governed by a complex balance of signals, including mitogenic stimuli that regulate cdo mRNA levels, and substratum-derived signals that regulate CDO protein production. cdo mRNA is expressed at low levels in most adult rat tissues. A closely related human gene maps to chromosome 11q23-24, a region that displays frequent loss of heterozygosity in human lung, breast, and ovarian tumors. Taken together, these data suggest that loss of CDO function could play a role in oncogenesis.

Extracellular ATP induces anchorage-independent expression of cyclin A and rescues the transformed phenotype of a ras-resistant mutant cell line.

Anchorage-independent growth is characteristic of neoplastic cells, but the signal transduction pathways that mediate this phenotype are poorly understood. Several important cell cycle events are dependent on cell-substratum adhesion in non-transformed cells, including activation of G1 cyclin-dependent kinases and expression of cyclin A; the adhesion requirement of these events is abrogated in Ras-transformed cells. The ER-1-2 mutant rat fibroblast cell line is: 1) resistant to Ras-mediated, anchorage-independent growth; 2) defective in Ras-mediated, adhesion-independent expression of cyclin A, but not adhesion-independent activation of cyclin-dependent kinases; and 3) rescued for Ras-induced, anchorage-independent growth by ectopic expression of cyclin A. We report here that extracellular ATP induces adhesion-independent expression of cyclin A and rescues growth in soft agar by ER-1-2 cells that express Ras. ADP, AMP and the non-hydrolyzable analog adenosine 5'-(beta, gamma-iminodiphosphate) are also effective, but adenosine is not. Adenine nucleotide-induced growth in soft agar is inhibited by reactive blue 2, an antagonist of some P2 purinoceptors. ATP does not induce adhesion-independent expression of cyclin A in ER-1-2 or control rat fibroblasts that do not express Ras, indicating a requirement for additional Ras-regulated signals for expression of this gene; one such signal may lead to phosphorylation of the retinoblastoma protein, pRB, and related proteins. These results suggest that extracellular ATP could play a role in the multistage carcinogenic process in vivo.

Ras induces anchorage-independent growth by subverting multiple adhesion-regulated cell cycle events.

Anchorage-independent growth is a hallmark of transformed cells, but little is known of the molecular mechanisms that underlie this phenomenon. We describe here studies of cell cycle control of anchorage-independent growth induced by the ras oncogene, with the use of a somatic cell mutant fibroblast line (ER-1-2) that is specifically defective in oncogene-mediated, anchorage-independent growth. Control, nontransformed PKC3-F4 cells and ER-1-2 cells cannot proliferate in semisolid medium. Three important cell cycle events are dependent on adhesion of these cells to a substratum: phosphorylation of the retinoblastoma protein, pRB; cyclin E-dependent kinase activity; and cyclin A expression. PKC3-F4 cells that express ras (PKC3-F4/ras cells) proliferate in nonadherent cultures, and each of these three events occurs in the absence of adhesion in PKC3-F4/ras cells. Thus, ras can override the adhesion requirement of cellular functions that are necessary for cell cycle progression. ER-1-2 cells that express ras (ER-1-2/ras cells) possess hyperphosphorylated forms of pRB and cyclin E-dependent kinase activity in the absence of adhesion but remain adhesion dependent for expression of cyclin A. The adhesion dependence of pRB phosphorylation and cyclin E-dependent kinase activity is therefore dissociable from the adhesion dependence of cyclin A expression. Furthermore, ectopic expression of cyclin A is sufficient to rescue anchorage-independent growth of ER-1-2/ras cells but does not induce anchorage-independent growth of PKC3-F4 or ER-1-2 cells. However, like pRB phosphorylation and cyclin E-dependent kinase activity, the kinase activity associated with ectopically expressed cyclin A is dependent on cell adhesion, and this dependence is overcome by ras. Thus, the induction of anchorage-independent growth by ras may involve multiple signals that lead to both expression of cyclin A and activation of G1 cyclin-dependent kinase activities in the absence of cell adhesion.

Dissociation of ras oncogene-induced gene expression and anchorage-independent growth in a series of somatic cell mutants.

The mechanism or mechanisms by which ras oncogenes induce morphological transformation and anchorage-independent growth are poorly understood but are thought to involve stable alterations in gene expression. We previously described a genetically dominant, mutant rat fibroblast cell line (ER-1-2) that is resistant to ras-induced anchorage-independent growth. We now describe a cell line derived from ER-1-2 cells, termed ER-1-2T, that has apparently sustained a second, dominant mutation that conferred on these cells the ability to form colonies in soft agar. Analysis of these and control cell lines demonstrated that deregulation of many of the genes commonly associated with the transformed phenotype could be dissociated from anchorage-independent growth. After infection with a ras-expressing retrovirus, both control and ER-1-2 cell lines constitutively expressed elevated levels of the c-jun, junB, fosB, c-myc, collagenase, ornithine decarboxylase, osteopontin, stromelysin, cathepsin L, and insulin-like growth factor 1 genes. These data indicate that signaling events downstream of ras were largely intact in ER-1-2 cells and that the defect in these cells lies either on a pathway separate from those that control stable, ras-mediated expression of these genes or at a point in the cell-division cycle distinct from those that control expression of the genes. In contrast, only c-jun, junB, c-myc, and ornithine decarboxylase were expressed at a significantly elevated level in ER-1-2T cells. Thus, deregulated expression of the genes analyzed was not sufficient for anchorage-independent growth. Furthermore, deregulation of most of them was also not necessary.

Autocrine secretion of osteopontin by vascular smooth muscle cells regulates their adhesion to collagen gels.

Osteopontin (OPN) is a secreted protein postulated to facilitate vascular smooth muscle cell (VSMC) adhesion and migration. Rat aortic VSMC lines were isolated after infection with recombinant retroviruses harboring OPN sense and antisense constructs. All lines grew normally in monolayer culture. On three-dimensional collagen gels, normal VSMCs and lines containing sense constructs (n=15) or empty vector (n=10) attached to gel and invaded the matrix. Four of five antisense clones did not adhere or invade. Antisense clones had lower OPN levels after stimulation with angiotensin II than sense clones or clones containing the empty vector (antisense, 257+/-102 ng/ml; sense, 473+/-104; vector, 434+/-66). Non-adhering antisense clones had lower mean OPN levels after angiotensin II stimulation (161+/-47 ng/ml) than sense or antisense lines with normal adhesion (486+/-63 ng/ml). The ability to adhere correlated with OPN levels >250 ng/ml. Adhesion and invasion were fully restored with addition of 100 to 200 ng/ml of exogenous OPN and were inhibited in normal VSMCs by incubation with 1 microgram/ml anti-OPN antibody. The autocrine secretion of OPN appears to play an important role in VSMC adhesion, spreading, and invasion.

Transformation-restoring factor: a low molecular weight secreted factor required for anchorage-independent growth of oncogene-resistant mutant cell lines.

We have previously described two independent mutant rat fibroblast cell lines that fail to form colonies in soft agar when infected with a v-H-ras-expressing retrovirus, yet still undergo transformation-related morphological alterations in response to this oncogene. We report here that conditioned medium (CM) from non-transformed rat fibroblasts contains an activity that specifically corrects this defect in the mutant cell lines, rendering them capable of anchorage-independent growth in response to ras. The major activity in CM, designated transformation-restoring factor (TRF), is approximately 1300 molecular weight, lipid insoluble, and heat, protease, acid and base stable. Latent activity, distinct from TRF, is also present in CM; several lines of evidence indicate that transforming growth factor (TGF) beta is responsible for this activity. TRF, however, cannot substitute for TGF beta in the phenotypic transformation of NRK cells. TRF activity is decreased in CM of control cells transformed by ras and this response to ras is retained by the mutant cell lines. We propose that whereas wild-type cells transformed by ras may constitutively activate a TRF-regulated pathway, thus becoming independent of TRF for growth in soft agar, these mutants have acquired dependence on an exogenous supply of TRF for this aspect of the transformed phenotype. Cellular activities regulated, directly or indirectly, by TRF may be effectors of the anchorage-independent growth property that is a hallmark of transformed rodent fibroblasts.

Effects of increased expression of protein kinase C on radiation-induced cell transformation.

The in vitro oncogenic transformation of C3H 10T1/2 cells by ionizing radiation is known to be enhanced by the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA). It is also known that the activation of protein kinase C (PKC) by TPA is an important step in its tumor-promoting effect. In the present study, we examined the effects of overexpression of a specific isoform of PKC, PKC beta 1 on gamma-ray-induced transformation of 10T1/2 cells. In addition, the effects of overexpression of PKC beta 1 on the malignant phenotype of a previously transformed 10T1/2 cell line were also evaluated. Derivatives of 10T1/2 cells that stably overexpress PKC beta 1 were obtained by transduction with the retroviral expression vector pMV7 carrying the rat PKC beta 1 cDNA sequence. We found that the parental 10T1/2 cells and a control cell line 10T1/2 MV7, which carried only the pMV7 vector without the cDNA insert, expressed dose-dependent transformation frequencies when exposed to gamma-rays. On the other hand, concurrently treated PKC-overexpressing cells that had an 11-fold increase in enzyme activity (PKC-4 cells) failed to yield any morphologically identifiable foci. Cell lines that expressed lower levels of PKC beta 1 were partially resistant to transformation by gamma-rays. Clonogenic survival data indicated that this observation was not due to radioresistance per se. Thus, overexpression of PKC beta 1 did not appear to function as an endogenous substitute for TPA in promoting radiation-induced transformation. Furthermore, overexpression of PKC did not reverse the transformation phenotypes in tumorigenic 10T1/2 cells once it was established. These findings are discussed with respect to the specific roles of individual isoforms of PKC in growth control.

The epsilon isoform of protein kinase C is an oncogene when overexpressed in rat fibroblasts.

We have overproduced the Ca(2+)-independent protein kinase C isoform, nPKC epsilon, in Rat 6 embryo fibroblasts, and examined the effects of this novel isoform on cell growth and transformation. As compared to vector control cell lines expressing only the hygromycin resistance gene, the nPKC epsilon overproducing cell lines exhibited a 7-13-fold increase in Ca(2+)-independent enzyme activity. Detailed analysis of seven individual nPKC epsilon overproducing clones indicated that those clones that expressed very high activity displayed a number of disorders in growth control, including: formation of dense foci in monolayer culture, decreased doubling time, increased saturation density, decreased serum requirement, growth in soft agar, and tumor formation in nude mice. These findings are in contrast to previous studies from our laboratory indicating that stable expression of high levels of cPKC beta 1 produced only a partially transformed phenotype (Housey et al., 1988). Taken together, these results provide the first direct evidence that distinct isoforms of PKC can exert different effects on growth control and malignant transformation in the same cell type.

Novel revertants of H-ras oncogene-transformed R6-PKC3 cells.

Rat 6 fibroblasts that overproduce protein kinase C beta 1 (R6-PKC3 cells) are hypersensitive to complete transformation by the T24 H-ras oncogene; yet T24 H-ras-transformed R6-PKC3 cells are killed when exposed to 12-O-tetradecanoylphorbol-13-acetate (TPA) (W.-L. W. Hsiao, G. M. Housey, M. D. Johnson, and I. B. Weinstein, Mol. Cell. Biol. 9:2641-2647, 1989). Treatment of an R6-PKC3 subclone that harbors a T24 H-ras gene under the control of an inducible mouse metallothionein I promoter with ZnSO4 and TPA is extremely cytocidal. This procedure was used to isolate rare revertants that are resistant to this toxicity. Two revertant lines, R-1a and ER-1-2, continue to express very high levels of protein kinase C enzyme activity but, unlike the parental cells, do not grow in soft agar. Furthermore, these revertants are resistant to the induction of anchorage-independent growth by the v-src, v-H-ras, v-raf, and, in the case of the R-1a line, v-fos oncogenes. Both revertant lines, however, retain the ability to undergo morphological alterations when either treated with TPA or infected with a v-H-ras virus, thus dissociating anchorage independence from morphological transformation. The revertant phenotype of both R-1a and ER-1-2 cells is dominant over the transformed phenotype in somatic cell hybridizations. Interestingly, the revertant lines no longer induce the metallothionein I-T24 H-ras construct or the endogenous metallothionein I and II genes in response to three distinct agents: ZnSO4, TPA, and dexamethasone. The reduction in activity of metallothionein promoters seen in these revertants may reflect defects in signal transduction pathways that control the expression of genes mediating specific effects of protein kinase C and certain oncogenes in cell transformation.

A novel, plasmid-based system for studying gene rearrangements in mammalian cells.

We have developed a plasmid-based system for isolating gene rearrangements in mammalian cells by selection for reversion of a promoterless drug resistance gene. pNH4 contains the selectable marker gene neo under the control of the herpes simplex virus, thymidine kinase (tk) promoter and, upstream and in the opposite orientation, a dormant promoterless hygromycin B resistance gene (hph) that can be expressed following rearrangement events. An NIH 3T3 cell line stably transfected with pNH4 that has a spontaneous frequency of generation of Hphr colonies of approximately 10(-8) was isolated. Treatment of this line with ethyl methanesulfonate raised the frequency of Hphr colony formation approximately 100-fold. Approximately 60% (21 of 35) of ethyl methanesulfonate-induced Hphr clones showed rearrangements detectable by Southern blot analysis within a 40-kb region surrounding the integrated construct, including a nonhomologous recombination event and, possibly, a large insertion. Additionally, three Hphr clones showed evidence of gene amplification. Northern (RNA) blot analysis of hph mRNA suggests that the rearrangements may provide a function that allows the tk promoter to initiate transcription off the opposite strand, thus yielding hph transcripts. Cell lines harboring pNH4, or modifications of it, may be valuable for studying recombination mechanisms responsible for the various types of genetic rearrangements found in cancer cells.

Characterization of a specific form of protein kinase C overproduced by a C3H 10T1/2 cell line.

Murine embryo fibroblasts (C3H 10T1/2) which were genetically engineered to overproduce the beta 1 isoform of protein kinase C (PKC-beta 1) were used to obtain homogeneous preparations of PKC-beta 1 for the purpose of characterizing the specific structural and functional properties of this isoform. Fractionation of PKC activity from these cells by hydroxyapatite chromatography produced one major peak, which represented 93% of the total cellular PKC activity and was not detected in control cells. This major peak of activity was shown by Western-blotting analysis with a beta 1-specific antiserum to be the overproduced beta 1-isoform, and exhibited a band at 77 kDa. The functional properties of the overproduced PKC-beta 1 were established with regard to phospholipid-dependence, Ca2(+)-dependence, responsiveness to a phorbol ester tumour promoter, activation by arachidonic acid (plus Ca2+), and inhibition by known PKC inhibitors. From these studies we conclude that PKC-beta 1 overproduced by C3H 10T1/2 cells exhibits the structural and functional properties previously ascribed to native PKC. Furthermore, these data provide the first definitive biochemical characteristics of this isoform of PKC.

Inhibition of rodent protein kinase C by the anticarcinoma agent dequalinium.

Dequalinium has previously been shown to be an anticarcinoma agent (M. J. Weiss et al., Proc. Natl. Acad. Sci. USA, 84: 5444-5448, 1987). The present study demonstrates that it can inhibit protein kinase C-beta 1 isolated from an overproducing cell line with a 50% inhibitory concentration of 8-15 microM. Further examination of the inhibition by using structural analogues of dequalinium reveals that the length of the methylene bridge between the two quinaldinium moieties, the presence of the ring substituents, and the bipartite character of the compound each contributes to the inhibitory potency. Related studies show that the analogues display the same rank order of inhibitory potency when tested with the trypsin-generated catalytic fragment of the enzyme, indicating that dequalinium inhibits kinase activity through an interaction with the catalytic subunit. Further studies argue that the ability of a given analogue to inhibit phosphotransferase activity correlates with its ability to compete with [3H]phorbol-12,13-dibutyrate binding on the intact enzyme (50% inhibitory concentration of 2-5 microM). This suggests that the inhibitor is either binding directly to the regulatory subunit as well, or that due to its interaction with the catalytic subunit, dequalinium produces an indirect effect on sites defined by phorbol ester binding. Kinetic analysis revealed that inhibition is noncompetitive with respect to ATP or phosphatidylserine. Studies conducted with types I, II, and III rat brain isozymes, resolved by hydroxylapatite chromatography, demonstrate that dequalinium inhibits each of them with similar potency (50% inhibitory concentration of 11 microM) and imply that the site of contact on the enzyme is a highly conserved region. Morphology studies with dequalinium in intact cells demonstrate that the inhibitor can protect control cells against phorbol ester-induced morphology changes but cannot protect protein kinase C-overproducing cells, suggesting that an elevation in protein kinase C levels alone is sufficient to overturn the protection conferred by dequalinium. On the basis of these results, we propose that protein kinase C could be a critical in vivo target of dequalinium.

Disturbances in growth control and gene expression in a C3H/10T1/2 cell line that stably overproduces protein kinase C.

We have utilized a retroviral expression vector to construct a series of C3H/10T1/2 murine fibroblast cell lines that stably overexpress a full length cDNA encoding rat protein kinase C beta 1 (PKC). These cell lines contain 3-11 fold greater PKC enzyme activity than parental cells or control cells that carry an integrated vector lacking the cDNA insert. 10T1/2-PKC-4, a line with an 11-fold increase in PKC activity, is morphologically altered, grows to 4-fold higher saturation density, and has decreased adhesiveness when compared to control cells. These cells also show constitutive and inducible alterations in the levels of two PKC-regulated genes, phorbin and TPA-R1. However, 10T1/2-PKC-4 cells do not have a transformed morphology, are incapable of growth in soft agar, and are non-tumorigenic in nude mice. When 10T1/2-PKC-4 cells are cultured in 2.5% calf serum and 100 ng ml-1 TPA, numerous large, dense foci appear 2-3 weeks after the cells reach confluence. TPA is required for focus formation, and control cells do not form foci under the same conditions. However, when such foci are isolated and grown in the absence of TPA, the cells closely resemble later passage 10T1/2-PKC-4 cells. Therefore, the events leading to focus formation appear to be reversible. The 10T1/2-PKC-4 cell line should be valuable for more precisely defining molecular events relevant to tumor promotion and multistage carcinogenesis.

The formation of 2-aminofluorene-DNA adducts in vivo: evidence for peroxidase-mediated activation.

Formation of DNA adducts in various tissues of dogs fed a single dose of the carcinogen 2-aminofluorene was investigated. Adduct analysis was performed using a technique that allows measurement of both N-(deoxyguanosin-8-yl)-2-amino-2-aminofluorene-DNA adduct formed by reaction of N-hydroxy-2-aminofluorene with DNA, as well as the polar 2-aminofluorene-DNA adducts formed when 2-aminofluorene is activated by prostaglandin H synthase-peroxidase in vitro. Two male beagle (A and B) dogs were examined and a different DNA adduct profile was observed with each dog. For the dog A, N-(deoxyguanosin-8-yl)-2-aminofluorene was the major adduct found in hepatic DNA; no peroxidase-derived adducts were detected in this tissue. In contrast, adducts eluting similarly to peroxidase-derived adducts were found in urinary tract tissues of this dog with the relative abundance of these adducts in the order urothelium greater than renal medulla greater than renal cortex, which correlates with the respective tissues' prostaglandin H synthase activity. N-(Deoxyguanosin-8-yl)-2-aminofluorene was detected in the renal tissues, but not in urothelium. For dog B, only the N-(deoxyguanosin-8-yl)-2-aminofluorene adduct was observed in all tissues examined, including the urothelium. However, total binding to liver, kidney, and bladder were two-, two-, and four-fold lower, respectively, than dog A. These data indicate that both prostaglandin H synthase-mediated activation and N-hydroxylation of 2-aminofluorene occur in vivo and may be subjected to pharmacodynamic considerations. Furthermore, the tissue distribution of the peroxidase-mediated 2-aminofluorene adducts suggests this process may also be of importance in the bladder-specific carcinogenicity of aromatic amines.

Macromolecular binding of the thyroid carcinogen 3-amino-1,2,4-triazole (amitrole) catalyzed by prostaglandin H synthase, lactoperoxidase and thyroid peroxidase.

3-Amino-1,2,4-triazole, a thyroid carcinogen and goitrogen, is negative in a wide variety of short-term mutagenicity assays. However, amitrole induces gene mutations and morphological transformation in Syrian hamster embryo fibroblasts, cells known to carry out the prostaglandin H synthase (PHS)-mediated peroxidative metabolism of other carcinogens. Therefore, we have investigated the peroxidase-mediated binding of [14C]amitrole to macromolecules in vitro. We report here the PHS- and lactoperoxidase-catalyzed binding of [14C]amitrole to protein and tRNA, as well as protein binding by rat and hog thyroid peroxidase. PHS was an order of magnitude more active than lactoperoxidase and two orders of magnitude more active than thyroid peroxidase. The low levels of binding observed with thyroid peroxidase could be explained by the rapid and potent inhibition of this enzyme by amitrole. Although the thyroid peroxidase-mediated binding of amitrole was quite low, it was not inhibitable by compounds that would be expected to be competing substrates in vivo (i.e. I-, monoiodotyrosine, diiodotyrosine). Neither catalase nor horseradish peroxidase catalyzed binding of [14C]amitrole. It was also observed that an interaction between amitrole and protein and/or nucleic acid resulted in the slow generation of hydrogen peroxide, which then served as a substrate to drive peroxidase-mediated binding of [14C]amitrole. These data suggest that PHS may be responsible for conversion of amitrole to a mutagenic intermediate in Syrian hamster embryo cells. Furthermore, the generation of reactive metabolites of amitrole by thyroid peroxidase and/or PHS may contribute to the complete carcinogenicity of this compound by adding a mutagenic response to its potent hormonal effects.