DNA topoisomerase II enzymes as molecular targets for cancer chemotherapy.

DNA topoisomerase II enzymes regulate essential cellular processes by altering the topology of chromosomal DNA. These enzymes function by creating transient double-stranded breaks in the DNA molecule that allow the DNA strands to pass through each other and unwind or unknot tangled DNA. Because of the integral role of topoisomerases in regulating DNA metabolism, these enzymes are vital for cell survival. Several clinically active antitumor agents target these enzymes. Mammalian cells contain two topoisomerase II isozymes that are encoded by different genes: topoisomerase IIα and IIß. Although, both isozymes are homologous and exhibit similar catalytic activity, they are differentially regulated and are involved in distinct biological functions. The topoisomerase IIα and topoisomerase IIß enzymes are regulated by post-translational modifications, including sumoylation, ubiquitination and phosphorylation. These post-translational modifications influence the biologic and catalytic activity of the enzyme and affect sensitivity of cells to topoisomerase II-targeted drugs. In this review, we describe how the catalytic and biologic activity of the topoisomerase II enzyme is regulated and discuss the mechanisms by which chemotherapeutic agents that target these enzymes function. Given the potential importance of site-specific modifications, in particular phosphorylation, in regulating sensitivity to topoisomerase II-targeted drugs, we discuss the potential role of altered topoisomerase II phosphorylation in development of drug resistance, which is often a limiting factor in the treatment of cancer.

Downregulation of topoisomerase IIbeta in myeloid leukemia cell lines leads to activation of apoptosis following all-trans retinoic acid-induced differentiation/growth arrest.

Among the topoisomerase (topo) II isozymes (alpha and beta), topo IIbeta has been suggested to regulate differentiation. In this study, we examined the role of topo IIbeta in all-trans retinoic acid (ATRA)-induced differentiation of myeloid leukemia cell lines. Inhibition of topo IIbeta activity or downregulation of protein expression enhanced ATRA-induced differentiation/growth arrest and apoptosis. ATRA-induced apoptosis in topo IIbeta-deficient cells involved activation of the caspase cascade and was rescued by ectopic expression of topo IIbeta. Gene expression profiling led to the identification of peroxiredoxin 2 (PRDX2) as a candidate gene that was downregulated in topo IIbeta-deficient cells. Reduced expression of PRDX2 validated at the mRNA and protein level, in topo IIbeta-deficient cells correlated with increased accumulation of reactive oxygen species (ROS) following ATRA-induced differentiation. Overexpression of PRDX2 in topo IIbeta-deficient cells led to reduced accumulation of ROS and partially reversed ATRA-induced apoptosis. These results support a role for topo IIbeta in survival of ATRA-differentiated myeloid leukemia cells. Reduced expression of topo IIbeta induces apoptosis in part by impairing the anti-oxidant capacity of the cell owing to downregulation of PRDX2. Thus, suppression of topo IIbeta and/or PRDX2 levels in myeloid leukemia cells provides a novel approach for improving ATRA-based differentiation therapy.

Cell cycle phase specificity in the potentiation of etoposide-induced DNA damage and apoptosis by KN-62, an inhibitor of calcium-calmodulin-dependent enzymes.

The cell cycle phase-dependent induction of DNA damage and apoptosis by etoposide (VP-16) and its modulation by 1-[N,O-bis(1, 5-isoquinolinesulfonyl)-N-methyl-l-tyrosyl]-4-piperazine (KN-62), an inhibitor of calcium-calmodulin-dependent enzymes, were examined in sensitive (HL-60/S) and VP-16-resistant (HL-60/DOX0.05) HL-60 cells. Cells from exponential-phase cultures were enriched by centrifugal elutriation into G(1), S, and G(2)+M fractions. Modulation of VP-16-induced apoptosis by KN-62 in HL-60/S cells was apparent only in the S phase at the IC(50) concentration. However, in the HL-60/DOX0.05 cells, significant (P < 0.001) potentiation of VP-16-induced apoptosis by a non-cytotoxic concentration of 2 microM KN-62 was apparent in cells in the G(1), S, and G(2)+M phases, as well as over the entire concentration range tested. VP-16-induced apoptosis and its potentiation by a non-cytotoxic concentration of 2 microM KN-62 were correlative with drug-stabilized DNA cleavable complex formation based on a band depletion assay. In agreement with the results on apoptosis in the resistant HL-60/DOX0.05 cells, the enhanced depletion of the alpha and beta isoforms of topoisomerase II by VP-16 + KN-62 was observed in G(1), S, and G(2)+M cells. Results suggest that the effects of KN-62 in reversing resistance are based on its role as a potent sensitizer of VP-16-induced DNA damage and apoptosis in a cell cycle phase-independent manner.

Roles of NF-kappaB and 26 S proteasome in apoptotic cell death induced by topoisomerase I and II poisons in human nonsmall cell lung carcinoma.

Activation of signaling pathways after DNA damage induced by topoisomerase (topo) poisons can lead to cell death by apoptosis. Treatment of human nonsmall cell lung carcinoma (NSCLC-3 or NSCLC-5) cells with the topo I poison SN-38 or the topo II poison etoposide (VP-16) leads to activation of NF-kappaB before induction of apoptosis. Inhibiting the degradation of IkappaBalpha by pretreatment with the proteasome inhibitor MG-132 significantly inhibited NF-kappaB activation and apoptosis but not DNA damage induced by SN-38 or VP-16. Transfection of NSCLC-3 or NSCLC-5 cells with dominant negative mutant IkappaBalpha (mIkappaBalpha) inhibited SN-38 or VP-16 induced transcription and DNA binding activity of NF-kappaB without altering drug-induced apoptosis. Regulation of apoptosis by mitochondrial release of cytochrome c and activation of pro-caspase 9 followed by cleavage of poly(ADP-ribose) polymerase by effector caspases 3 and 7 was similar in neo and mIkappaBalpha cells treated with SN-38 or VP-16. In contrast to pretreatment with MG-132, exposure to MG-132 after SN-38 or VP-16 treatment of neo or mIkappaBalpha cells decreased cell cycle arrest in the S/G2 + M fraction and enhanced apoptosis compared with drug alone. In summary, apoptosis induced by topoisomerase poisons in NSCLC cells is not mediated by NF-kappaB but can be manipulated by proteasome inhibitors.

Altered drug interaction and regulation of topoisomerase IIbeta: potential mechanisms governing sensitivity of HL-60 cells to amsacrine and etoposide.

Topoisomerase II (topo II), an enzyme essential for cell viability, is present in mammalian cells as the alpha- and beta-isoforms. In human leukemia HL-60/S or HL-60/doxorubicin (DOX)0.05 cells, the levels of topo IIalpha- or beta-protein were similar in either asynchronous exponential or synchronized cultures. Although topo IIalpha was hypophosphorylated in HL-60/DOX0.05 compared with HL-60/S cells, both overall and site-specific hyperphosphorylation of topo IIbeta was apparent in HL-60/DOX0.05 compared with HL-60/S cells. The phosphorylation of topo IIalpha and not beta was enhanced in the S and G(2) + M phases of HL-60/S cells. In contrast, an increase in the phosphorylation of topo IIbeta compared with alpha was apparent in the G(1) and S phases of HL-60/DOX0.05 cells. The cytotoxicity and depletion of topo IIalpha or beta in cells treated with drug for 1 h revealed that mole-for-mole, amsacrine was 2-fold more effective than etoposide in killing HL-60/S or HL-60/DOX0.05 cells and in depleting the beta versus alpha topo II protein. Present results demonstrate that: 1) hyperphosphorylation of topo IIbeta in HL-60/DOX0.05 cells may be a compensatory consequence of the hypophosphorylation of topo IIalpha to maintain normal topo II function during proliferation, and 2) enhanced sensitivity of HL-60/S or HL-60/DOX0.05 cells to amsacrine may be due to the preferential interaction and depletion of topo IIbeta.

Attenuation of drug-stimulated topoisomerase II-DNA cleavable complex formation in wild-type HL-60 cells treated with an intracellular calcium buffer is correlated with decreased cytotoxicity and site-specific hypophosphorylation of topoisomerase IIalpha.

Topoisomerase II (topo II), an essential enzyme for cell viability, is also the target for clinically important anti-neoplastic agents that stimulate topo II-mediated DNA scission. The role of alterations in topo IIalpha phosphorylation and its effect on drug-induced DNA damage and cytotoxicity were investigated. Following loading of HL-60 cells with the calcium buffer 1, 2-bis-(o-aminophenoxy)ethane-N,N,N',N'-tetra-acetic acid tetra(acetoxymethyl) ester (BAPTA-AM), which abrogates intracellular Ca2+ transients, a significant decrease in etoposide (VP-16)- or amsacrine (m-AMSA)-stabilized topo II-DNA cleavable complex formation and a corresponding decrease in cytotoxicity was observed. In a cell-free system, nuclear extracts from BAPTA-AM-treated cells exhibited markedly less activity when assayed for VP-16-stabilized topo II-DNA complex formation, but not decatenation of kinetoplast DNA. In contrast, the loading of HL-60 cells with N,N,N', N'-tetrakis-(2-pyridyl)ethylenediamine (TPEN), which binds heavy metals without disturbing calcium or magnesium concentrations, did not significantly affect VP-16-stimulated topo II-DNA cleavable complex formation or cytotoxicity. In HL-60 cells the accumulation of BAPTA, but not TPEN, also led to the hypophosphorylation of topo IIalpha. Tryptic phosphopeptide mapping of topo IIalpha protein from HL-60 cells revealed: (a) eight major phosphorylation sites in untreated cells; (b) hypophosphorylation of two out of eight sites in BAPTA-AM-treated cells; and (c) hypophosphorylation of between two and four out of eight sites in topo II-poison-resistant HL-60 cells. The two hypophosphorylated sites present following BAPTA-AM treatment of wild-type cells were identical with the hypophosphorylated sites in the resistant cells, but were not the same as the sites that are substrates for casein kinase II [Wells, Addison, Fry, Ganapathi and Hickson (1994) J. Biol. Chem. 269, 29746-29751]. In summary, changes in intracellular Ca2+ transients that lead to the site-specific hypophosphorylation of topo IIalpha are possibly involved in regulating the DNA damage caused by and the cytotoxic potential of topo II poisons.

Altered expression and activity of topoisomerases during all-trans retinoic acid-induced differentiation of HL-60 cells.

Regulation of topoisomerase II (TOPO II) isozymes alpha and beta is influenced by the growth and transformation state of cells. Using HL-60 cells induced to differentiate by all-trans retinoic acid (RA), we have investigated the expression and regulation of TOPO II isozymes as well as the levels of topoisomerase I (TOPO I). During RA-induced differentiation of human leukemia HL-60 cells, levels of TOPO I remained unchanged, whereas the levels and phosphorylation of TOPO IIalpha and TOPO IIbeta proteins were increased twofold to fourfold and fourfold to eightfold, respectively. The elevation of TOPO II (alpha and beta) protein levels and phosphorylation was apparent at 48 hours of treatment with RA and persisted through 96 hours. The increased level of TOPO IIbeta protein was also detected in differentiated cells subsequently cultured for 96 hours in RA-free medium. Pulse chase experiments in cells labeled with 35S-methionine showed that the rate of degradation of TOPO IIbeta protein in control cells was about twofold faster than that in the differentiated RA-treated cells. The level of decatenation activity of kDNA was comparable in nuclear extracts from control or RA-treated cells. Whereas etoposide (1 to 10 micromol/L) -induced DNA cleavage was not significantly different, apoptosis was significantly lower (P = .012) in RA-treated versus control cells after exposure to 10 micromol/L etoposide. Consistent with unaltered levels of TOPO I, camptothecin (CPT) -induced DNA cleavage was similar in control or RA-treated cells. However, apoptosis after exposure to 1 to 10 micromol/L CPT was significantly lower (P = .003 to P < .001) in RA-treated versus control cells. Results suggest that TOPO IIbeta protein levels are posttranscriptionally regulated and that degradation of TOPO IIbeta is decreased during RA-induced differentiation. Furthermore, whereas the total level of TOPO II (alpha + beta) is increased with RA, the level of TOPO II catalytic activity and etoposide-stabilized DNA cleavage activity remains unaltered. Thus, TOPO IIbeta may have a specific role in transcription of genes involved in differentiation with RA treatment.

Interleukin 6 differentially potentiates the antitumor effects of taxol and vinblastine in U266 human myeloma cells.

Newer therapeutic strategies for the treatment of multiple myeloma have focused on antagonizing the growth-promoting functions of interleukin 6 (IL-6). In this study, we examined the antitumor effects of two mechanistically different microtubule poisons, Taxol and vinblastine, in U266 human myeloma cells and determined whether IL-6 altered these effects. Taxol and vinblastine led to a dose-dependent inhibition of [3H]thymidine incorporation and altered the DNA distribution pattern of U266 cells. Both drugs led to an increase in the proportion of cells in the sub-G1 fraction (<2N DNA). However, at the IC50 concentration, vinblastine, but not Taxol, increased the percentage of cells in the G2-M phase of the cell cycle. In the presence of IL-6, the DNA distribution pattern induced by Taxol or vinblastine was altered. Whereas IL-6 augmented the sub-G1 fraction and G2-M phase for Taxol-treated cells, only the G2-M phase was increased for vinblastine-treated cells. Furthermore, IL-6 enhanced the cytotoxicity of both drugs, which became evident only during recovery in cytokine-free and drug-free medium. However, the cytotoxicity of Taxol was augmented to a significantly greater extent than that of vinblastine (P < 0.001). Immunostaining with antibodies to alpha-tubulin and mitogen-activated protein kinase revealed colocalization of these two proteins within microtubule asters. In the presence of IL-6, the number of cells containing microtubule asters increased for Taxol treatment, but not for vinblastine treatment. These data indicate that IL-6 leads to differential modulation of the cytotoxicity of Taxol and vinblastine in U266 cells. Whereas recruitment of cells in the S phase of the cell cycle represents a major mechanism by which IL-6 potentiates the cytotoxicity of vinblastine, augmentation of the cytotoxicity of Taxol involves additional mechanisms. Furthermore, our data suggest that the microtubule-associated form of mitogen-activated protein kinase may play a role in IL-6-mediated enhancement of the cytotoxicity of Taxol. The clinical implications of these findings are discussed.

Resistance to interleukin 6 in human non-small cell lung carcinoma cell lines: role of receptor components.

The role of interleukin 6 (IL-6) in regulating the growth of three human non-small cell lung carcinoma (NSCLC) cell lines (NSCLC-3, NSCLC-5, and NSCLC-7, derived from a primary lesion, a brain lesion, and lymph node metastases, respectively) was examined. Although IL-6 alone did not alter the growth of these cells, the addition of soluble IL-6 receptor (sIL-6R) led to the inhibition of proliferation of one of the NSCLC cell lines, NSCLC-5. This antiproliferative effect was neutralized by antibodies to IL-6 and the IL-6R binding and signaling component (gp130). The IL-6-related cytokines, leukemia inhibitory factor and oncostatin M, inhibited proliferation of NSCLC-5 cells but were ineffective in NSCLC-3 and NSCLC-7 cells. NSCLC-7 cells (but not NSCLC-3 or NSCLC-5 cells) secreted biologically active IL-6 and expressed IL-6R. However, antibodies to IL-6 or gp130 failed to alter the proliferation of NSCLC-7 cells. All three cell lines expressed gp130 mRNA and protein. The level of expression of gp130 protein varied in the three cell lines (NSCLC-7 > NSCLC-3 > NSCLC-5). The examination of tyrosine phosphorylation of gp130 (as an early event in IL-6 signal transduction) revealed that gp130 could be phosphorylated in all cell lines after stimulation with IL-6 and/or IL-6 + sIL-6R. These results demonstrate that the mechanisms responsible for IL-6 resistance in different NSCLC cell lines vary and involve defects at either one or more levels of the IL-6 signaling cascade. In the NSCLC-5 cell line, IL-6 resistance (which can be reversed in the presence of sIL-6R) is due to the transcriptional inactivation of the IL-6R gene. In contrast, in the other two cell lines (NSCLC-3 and NSCLC-7), defect(s) in the signaling cascade downstream of gp130 phosphorylation, together with a lack of expression of IL-6R in NSCLC-3 cells, result in IL-6 resistance.

Okadaic acid, an inhibitor of protein phosphatases 1 and 2A, inhibits induction of acute-phase proteins by interleukin-6 alone or in combination with interleukin-1 in human hepatoma cell lines.

Okadaic acid (OA), a specific inhibitor of protein phosphatases 1 and 2A, inhibited in a dose-dependent manner (5-20 nM) the induction of C-reactive protein (CRP), serum amyloid A (SAA) and fibrinogen by interleukin-6 (IL-6) plus interleukin-1 (IL-1), and of fibrinogen by IL-6 alone, in Hep 3B cells. Induction of alpha 1-proteinase inhibitor (alpha 1-PI) by IL-6 plus IL-1 or IL-6 alone was not significantly affected by OA up to concentrations of 20 nM, above which concentration OA was toxic in Hep 3B cells. OA also inhibited the induction of CRP, fibrinogen and alpha 1-PI by IL-6 in the NPLC/PRF/5 cell line, albeit at a higher concentration (80 nM). These results suggest that the signal transduction mechanisms regulating induction of acute-phase proteins by IL-6, either alone or in combination with IL-1, are mediated by activation of protein phosphatases 1 and/or 2A.

Effect of combinations of cytokines and hormones on synthesis of serum amyloid A and C-reactive protein in Hep 3B cells.

We have previously shown that induction of synthesis of the two major human acute phase proteins, serum amyloid A (SAA) and C-reactive protein (CRP), can be accomplished in the human hepatoma cell line Hep 3B, in the presence of dexamethasone, either by conditioned medium from LPS-stimulated monocytes or by the combination of IL-6 and IL-1. Neither of these cytokines alone caused significant induction of either SAA or CRP. In the present study we extended our earlier observations by evaluating the role of dexamethasone, the effect of different concentrations of IL-6 and IL-1 alpha in combination, and the possible role of TNF-alpha in regulating synthesis of SAA and CRP. Dexamethasone alone had no effect on induction of SAA or CRP. Incubation of Hep 3B cells with conditioned medium from LPS-stimulated monocytes, in the absence of dexamethasone, led to modest induction of SAA or CRP, but addition of dexamethasone potentiated this response in a dose-dependent manner. Similar results were obtained for the effect of dexamethasone on the induction of SAA by IL-6 plus IL-1 alpha. Checkerboard titration of IL-6 and IL-1 alpha revealed that increases in concentration of either cytokine led to dose-related increases in synthesis of both SAA and CRP as long as a minimal amount of the other cytokine was present. TNF-alpha alone had no significant effect on synthesis of either SAA or CRP, but the combination of IL-6 plus TNF-alpha led to substantial induction of SAA. This combination was less effective than the combination of IL-6 plus IL-1 alpha. No detectable effect of IL-6 plus TNF-alpha was observed on CRP synthesis. Both combinations of cytokines, IL-6 plus IL-1 alpha, and IL-6 plus TNF-alpha, caused increased SAA mRNA accumulation that roughly paralleled increase in synthesis. These data indicate that IL-6, IL-1 alpha, TNF-alpha, and dexamethasone in various combinations are all capable of influencing synthesis of SAA in Hep 3B cells, whereas only IL-6, IL-1 alpha, and dexamethasone can influence CRP synthesis.

Effects of cytokine combinations on acute phase protein production in two human hepatoma cell lines.

We evaluated the effects of binary combinations of four cytokines on production of the positive acute phase proteins alpha-1 antichymotrypsin, haptoglobin and fibrinogen, and the negative acute phase proteins albumin and alpha-fetoprotein (AFP) in two human hepatoma cell lines. The effects of the cytokine combinations on the five proteins varied; each protein exhibited a unique and specific pattern of response to the cytokine combinations. In Hep G2 cells, antichymotrypsin was induced by all four cytokines, IL-6, IL-1, TNF-alpha, and transforming growth factor beta 1 alone, and their effects in binary combinations could be attributed to additive or minimally synergistic interactions. Fibrinogen was induced only by IL-6 and this induction was inhibited by IL-1 alpha, TNF-alpha or transforming growth factor beta 1. Haptoglobin was also induced only by IL-6, but TNF-alpha was the only cytokine that inhibited this induction at all concentrations of IL-6. Each of the four cytokines alone down regulated production of AFP and albumin. However, binary combinations of the four cytokines were simply additive, for the most part, in inhibiting AFP production, whereas the inhibitory effects of combinations of cytokines on albumin production differed significantly from simple additive effects. These observations, taken together with studies of effects of cytokine combinations on other acute phase proteins, indicate that the various acute phase proteins respond differently to different combinations of cytokines and that the potential exists for highly specific regulation of synthesis of individual plasma proteins by cytokine interactions. These findings imply that the acute phase response in vivo represents the integrated sum of multiple, separately regulated changes in gene expression.

Induction of C-reactive protein by cytokines in human hepatoma cell lines is potentiated by caffeine.

Induction of C-reactive protein (CRP) by conditioned medium from lipopolysaccharide-stimulated human monocytes in two human hepatoma-cell lines, Hep 3B and NPLC/PRF/5, was potentiated 3-6-fold by the methylxanthine caffeine. The induction observed in the presence of conditioned medium plus caffeine was as much as 180-fold, comparable with that seen after many stimuli in vivo. This potentiation was accompanied by an increase in the levels of CRP mRNA. By contrast, no potentiating effect on CRP induction by conditioned medium was found when we tested theophylline, forskolin, 8-bromo cyclic AMP or two Ca2+ ionophores, namely ionomycin and A23187. None of the above compounds, including caffeine, when tested alone, had any detectable effect on the synthesis and secretion of CRP. Our previous study [Ganapathi, May, Schultz, Brabenec, Weinstein, Sehgal & Kushner (1988) Biochem. Biophys. Res. Commun. 157, 271-277], employing defined cytokines, had shown that induction of CRP in Hep 3B cells requires IL(interleukin)-6 plus IL-1, whereas, in the NPLC/PRF/5 cell line, IL-6 alone is effective. Caffeine similarly potentiated induction of CRP by these defined cytokine signals in these two cell lines. Changes in synthesis of other acute-phase proteins, including serum amyloid A (SAA), alpha 1-proteinase inhibitor, alpha 1-antichymotrypsin and albumin, induced by conditioned medium or, in some cases, by IL-6 and/or IL-1 alpha, were only minimally affected by caffeine. Thus these results indicate that the mechanism by which caffeine potentiates CRP induction by cytokines appears to be independent of increases in intracellular concentrations of the two second messengers, cyclic AMP and Ca2+; the precise nature of this mechanism is unclear at the present time. Our results also indicate that the intracellular mechanisms by which cytokines regulate synthesis of CRP may differ from those regulating synthesis of some other acute-phase proteins. The differential response of CRP and SAA to caffeine is of particular interest, since induction of both of these two major acute-phase proteins can be accomplished by identical extracellular signals.

Transforming growth factor beta 1 regulates production of acute-phase proteins.

We explored the possible role of transforming growth factor beta 1 (TGF-beta), a cytokine that appears to be an important modulator of inflammation and tissue repair, in regulation of human plasma protein synthesis during the acute-phase response. In Hep 3B cells, TGF-beta led to increased secretion of the positive acute-phase proteins alpha 1-protease inhibitor and alpha 1-antichymotrypsin and decreased secretion of the negative acute-phase protein albumin. In Hep G2 cells, after incubation with TGF-beta, the same changes in secretion of alpha 1-protease inhibitor, alpha 1-antichymotrypsin, and albumin were observed, as well as decreased secretion of both the negative acute-phase protein alpha-fetoprotein and the positive acute-phase protein fibrinogen. In addition, TGF-beta modulated the effects of interleukin 6; these cytokines, in combination, were additive in inducing synthesis and secretion of alpha 1-protease inhibitor and alpha 1-antichymotrypsin and in decreasing secretion of albumin and alpha-fetoprotein. TGF-beta inhibited the induction of fibrinogen caused by interleukin 6. The effects on alpha 1-protease inhibitor were confirmed by metabolic labeling in Hep 3B cells and by demonstrating increased accumulation of specific mRNA in Hep G2 cells, and the effects on fibrinogen were confirmed in Hep 3B cells by studies of mRNA for the alpha chain of fibrinogen. TGF-beta had no effect on haptoglobin or alpha 1-acid glycoprotein secretion, either directly or in the presence of interleukin 6, which is capable of inducing these proteins. These studies demonstrate that TGF-beta can affect hepatic synthesis and secretion of a subset of acute-phase proteins, both directly and by modulating the effect of interleukin 6. The affected group of plasma proteins is distinct from those affected by other recognized acute-phase protein-inducing cytokines. These findings support the view that combinations of cytokines mediate the response of the hepatocyte to inflammatory stimuli.

Regulation of rabbit acute phase protein biosynthesis by monokines.

We defined the acute phase behaviour of a number of rabbit plasma proteins in studies (in vivo) and studied the effects of monokine preparations on their synthesis by rabbit primary hepatocyte cultures. Following turpentine injection, increased serum levels of C-reactive protein, serum amyloid A protein, haptoglobin, ceruloplasmin, and decreased concentrations of albumin were observed. In contrast to what is observed in man, concentrations of alpha 2-macroglobulin and transferrin were increased. Co-culture of primary hepatocyte cultures with lipopolysaccharide-activated human peripheral blood monocytes or incubation with conditioned medium prepared from lipopolysaccharide-activated human or rabbit monocytes resulted in dose-dependent induction of serum amyloid A, haptoglobin, ceruloplasmin and transferrin and depression of albumin synthesis, while C-reactive protein synthesis and mRNA levels remained unchanged. A variety of interleukin-1 preparations induced dose-dependent increases in the synthesis and secretion of serum amyloid A, haptoglobin, ceruloplasmin and transferrin and decreased albumin synthesis. Human recombinant tumour necrosis factor (cachectin) induced a dose-dependent increase in synthesis of haptoglobin and ceruloplasmin. In general, human interleukin-1 was more potent than mouse interleukin-1 and tumour necrosis factor. None of the monokines we studied had an effect on C-reactive protein synthesis or mRNA levels. These data confirm that C-reactive protein, serum amyloid A, haptoglobin and ceruloplasmin display acute phase behaviour in the rabbit, and demonstrate that, in contrast to their behaviour in man, alpha 2M and transferrin are positive acute phase proteins in this species. While both interleukin-1 and tumour necrosis factor regulate biosynthesis of a number of these acute phase proteins in rabbit primary hepatocyte cultures, neither of these monokines induced C-reactive protein synthesis. Comparison of these findings with those in human hepatoma cell lines, in which interleukin-1 does not induce serum amyloid A synthesis, suggests that the effect of interleukin-1 on serum amyloid A synthesis may be indirect.

Heterogeneous nature of the acute phase response. Differential regulation of human serum amyloid A, C-reactive protein, and other acute phase proteins by cytokines in Hep 3B cells.

Because a number of different cytokines have been reported to regulate the synthesis of human, murine, and rat acute phase proteins (APP), we studied the effect of cytokines on production of several major human APP in a single system, the human hepatoma cell line Hep 3B. Conditioned medium (CM) prepared from human blood monocytes activated with LPS in the presence of dexamethasone led to substantial induction of serum amyloid A (SAA) and C-reactive protein (CRP) synthesis whereas the defined cytokines IL-1 beta, TNF alpha, and medium from a human keratinocyte cell line (COLO-16), containing hepatocyte-stimulating factor activity, failed to induce these two major APP. Induction of SAA and CRP was accompanied by an increase in concentration of their specific mRNA. Size fractionation of CM from activated monocytes by fast protein liquid chromatography indicated that SAA- and CRP-inducing activity eluted as a single peak with a Mr of approximately 18 kDa. alpha 1-Antitrypsin, which also failed to respond to IL-1 beta or TNF alpha, was induced by both CM and medium from COLO-16 cells. The induction of AT by CM was accompanied by an increase in specific mRNA. Induction of ceruloplasmin and alpha 1-antichymotrypsin and decrease in the synthesis of albumin was achieved by both CM and IL-1 beta. Ceruloplasmin and albumin responded in a comparable fashion to both TNF alpha and medium from COLO-16 cells; the response of ACT to these cytokines was not evaluated. These results indicate that human SAA and CRP are induced in Hep 3B cells by products of activated monocytes but not by IL-1 beta, TNF-alpha, or some hepatocyte-stimulating factor preparations and that a group of heterogeneous mechanisms are involved in the induction of the various human APP.

Cloning and cDNA sequence of the dihydrolipoamide dehydrogenase component human alpha-ketoacid dehydrogenase complexes.

cDNA clones comprising the entire coding region for human dihydrolipoamide dehydrogenase (dihydrolipoamide:NAD+ oxidoreductase, EC 1.8.1.4) have been isolated from a human liver cDNA library. The cDNA sequence of the largest clone consisted of 2082 base pairs and contained a 1527-base open reading frame that encodes a precursor dihydrolipoamide dehydrogenase of 509 amino acid residues. The first 35-amino acid residues of the open reading frame probably correspond to a typical mitochondrial import leader sequence. The predicted amino acid sequence of the mature protein, starting at the residue number 36 of the open reading frame, is almost identical (greater than 98% homology) with the known partial amino acid sequence of the pig heart dihydrolipoamide dehydrogenase. The cDNA clone also contains a 3' untranslated region of 505 bases with an unusual polyadenylylation signal (TATAAA) and a short poly(A) track. By blot-hybridization analysis with the cDNA as probe, two mRNAs, 2.2 and 2.4 kilobases in size, have been detected in human tissues and fibroblasts, whereas only one mRNA (2.4 kilobases) was detected in rat tissues.

Cloning of rat brain succinyl-CoA:3-oxoacid CoA-transferase cDNA. Regulation of the mRNA in different rat tissues and during brain development.

3-Oxoacid CoA-transferase, which catalyses the first committed step in the oxidation of ketone bodies, is uniquely regulated in developing rat brain. Changes in 3-oxoacid CoA-transferase activity in rat brain during the postnatal period are due to changes in the relative rate of synthesis of the enzyme. To study the regulation of this enzyme, we identified, with a specific polyclonal rabbit anti-(rat 3-oxoacid CoA-transferase), two positive cDNA clones (approx. 800 bp) in a lambda gtll expression library, constructed from poly(A)+ RNA from brains of 12-day-old rats. One of these clones (lambda CoA3) was subcloned into M13mp18 and subjected to further characterization. Labelled single-stranded probes prepared by primer extension of the M13mp18 recombinant hybridized to a 3.6 kb mRNA. Rat brain mRNA enriched by polysome immunoadsorption for a single protein of size 60 kDa which corresponds to the precursor form of 3-oxoacid CoA-transferase was also found to be similarly enriched for the hybridizable 3.6 kb mRNA complementary to lambda CoA3. Affinity-selected antibody to the lambda CoA3 fusion protein inhibited 3-oxoacid CoA-transferase activity present in rat brain mitochondrial extracts. The 3.6 kb mRNA for 3-oxoacid CoA-transferase was present in relative abundance in rat kidney and heart, to a lesser extent in suckling brain and mammary gland and negligible in the liver. The specific mRNA was also found to be 3-fold more abundant in the brain from 12-day-old rats as compared with 18-day-old foetuses and adult rats, corresponding to the enzyme activity and relative rate of synthesis profile during development. These data suggest that 3-oxoacid CoA-transferase enzyme activity is regulated at a pretranslational level.

Monokines regulate glycosylation of acute-phase proteins.

The acute-phase response to inflammatory stimuli, characterized by increased synthesis of acute-phase proteins (APP), is often accompanied by changes in the glycosylation patterns of some of these proteins. While expression of APP genes in hepatocytes is regulated by monokines, mechanisms governing changes in glycosylation are not known. Exposure of human hepatoma cell line Hep 3B to conditioned medium from LPS-activated human monocytes and to medium from the keratocarcinoma cell line COLO-16 led to increased synthesis of alpha 1 proteinase-inhibitor and ceruloplasmin and to alterations of their glycosylation patterns similar to those seen in human serum in various inflammatory states. IL-1, tumor necrosis factor, and hepatocyte stimulating factor I increased synthesis of ceruloplasmin without alterations in the pattern of its glycosylation. These findings demonstrate that altered glycosylation seen in plasma in some inflammatory states can be explained by the effects of monokines on glycosylation in hepatocytes and that gene expression and glycosylation of some APP during the acute-phase response may be regulated by different mechanisms.