Functional characteristics of in vitro generated macrophages: a transient refractory state precedes reinducibility of a spatially restricted, possibly contact-dependent, cytostatic mechanism

Adherent layers of macrophages (M phi-c) generated in vitro from splenic precursors previously have been shown to inhibit proliferation of normal and neoplastic cells by mechanisms that do not involve the secretion of significant quantities of prostaglandins, peroxides, or proteases. In the current report, it is demonstrated that the effective range of the cytostatic effect of adherent M phi-c is so low that cytostasis can be circumvented by preventing the target cells from settling to the adherent layer by incubating the cultures of targets and M phi-c on a rocking platform. Despite the paucity of production of inhibitory mediators, the M phi-c do produce sufficient IL-1 to restore IL-2 production capacity to macrophage-depleted lymphocyte populations. The cytostatic activity of the M phi-c is an inducible event and remains for several days in the continuous presence of mitogen-activated lymphocytes or LPS + lymphokines. Once the activators are removed the cytostatic activity rapidly declines, reaching background levels in 24-48 hr. Maximal cytostatic activity can be reinduced but only 48 hr or longer after the primary activators were removed. A transient period in which the M phi-c are refractory to reactivation can be demonstrated to exist for 1-2 days after removal of the primary activators.     

Dichloroacetate causes reversible demyelination in vitro: potential mechanism for its neuropathic effect

Dichloroacetate (DCA) is an investigational drug for genetic mitochondrial diseases whose use has been mitigated by reversible peripheral neuropathy. We investigated the mechanism of DCA neurotoxicity using cultured rat Schwann cells (SCs) and dorsal root ganglia (DRG) neurons. Myelinating SC-DRG neuron co-cultures, isolated SCs and DRG neurons were exposed to 1-20 mm DCA for up to 12 days. In myelinating co-cultures, DCA caused a dose- and exposure-dependent decrease of myelination, as determined by immunolabeling and immunoblotting for myelin basic protein (MBP), protein zero (P0), myelin-associated glycoprotein (MAG) and peripheral myelin protein 22 (PMP22). Partial recovery of myelination occurred following a 10-day washout of DCA. DCA did not affect the steady-state levels of intermediate filament proteins, but promoted the formation of anti-neurofilament antibody reactive whirls. In isolated SC cultures, DCA decreased the expression of P0 and PMP22, while it increased the levels of p75(NTR) (neurotrophin receptor), as compared with non-DCA-treated samples. DCA had modest adverse effects on neuronal and glial cell vitality, as determined by the release of lactate dehydrogenase. These results demonstrate that DCA induces a reversible inhibition of myelin-related proteins that may account, at least in part, for its clinical peripheral neuropathic effects.     

Overexpression of cyclooxygenase-2 induces cell cycle arrest. Evidence for a prostaglandin-independent mechanism

The immediate-early gene cyclooxygenase 2 (Cox-2) is induced in a variety of hyperplastic pathological conditions, including rheumatoid arthritis and colorectal cancer. Although a causal role for Cox-2 has been proposed, mechanisms by which Cox-2 function contributes to the pathogenesis of hyperplastic disease are not well defined. We constructed a green fluorescent protein-tagged Cox-2 (Cox-2-GFP) to examine its effects on a variety of cell types upon overexpression. Subcellular localization and enzymatic and pharmacological properties of Cox-2-GFP polypeptide were indistinguishable from those of the wild-type Cox-2 polypeptide. Overexpression of the Cox-2-GFP or the Cox-2 polypeptide by transient transfection suppressed the population of cells in the S phase of the cell cycle, with a concomitant increase in G(0)/G(1) population. In contrast, transient overexpression of GFP had no effect on cell cycle distribution, whereas endoplasmic reticulum-retained GFP (GFP-KDEL) overexpression was associated with only a minor decrease of cells in S phase. Interestingly, neither NS-398 (a Cox-2-specific inhibitor) nor indomethacin could reverse the effect of Cox-2-GFP overexpression on cell cycle progression. Furthermore, two mutants of Cox-2, S516Q and S516M, which lack the cyclooxygenase activity, exhibited the same effect as Cox-2-GFP. The cell cycle effect of Cox-2-GFP was observed in ECV-304, NIH 3T3, COS-7, bovine microvascular endothelial cells, and human embryonic kidney 293 cells. These findings suggest that Cox-2 inhibits cell cycle progression in a variety of cell types by a novel mechanism that does not require the synthesis of prostaglandins.     

Efficient synthesis and in vitro cytostatic activity of 4-substituted triazolyl-nucleosides

We report herein an efficient synthesis of 4-substituted triazolyl-nucleosides and their in vitro cytostatic activity. The synthesis is based on a straightforward 1,3-dipolar cycloaddition between 1-azido-ribose 2 and terminal alkynes under a cooperative effect of microwave activation and copper (I) catalysis. All cycloadducts were obtained in nearly quantitative yield after a short reaction time (1 to 2min). After removal of acetyl protecting groups, the free nucleosides were evaluated against L1210, Molt4/C8, and CEM tumor cell lines. Structure-activity relationship study shows that the substituent on the triazole ring has a major effect since nucleosides 4c and 4g, containing, respectively, a long alkyl chain and an aryl donor group are the most active compounds in this series.     

Cytostatic effect of gangliosides present in the membrane of macrophages

Stimulated macrophages are known to inhibit the growth of certain tumor cells. Using mouse peritoneal exudates as a source of macrophages and the mastocytoma cell line P815 as the target, the inhibition was found to depend on direct contact between the macrophages and the growing cells. Cytostatic activities were detected in extracts of macrophages as well as in membranes of macrophages bound to substances of low molecular weight. Physical and biochemical characteristics of the cytostatic activity hint toward N-acetylneuraminic acid containing glycosphingolipids (gangliosides). The different macrophage gangliosides were separated by thin-layer chromatography. All types showed cytostatic activity, but the most effective gangliosides were identified as monosialoganglioside GM1 and disialoganglioside GD3.     

Arachidonic acid stimulates interleukin-6 release from rat peritoneal macrophages in vitro: Evidence for a prostacyclin-dependent mechanism

Interleukin-6 (IL-6) is a cytokine involved in the differentiation of B-cells to antibody secreting plasma cells, the activation of T-cells, and the stimulation of hepatocyte production of acute phase proteins. Because of the pro-inflammatory effects of this cytokine, we investigated the ability of the fatty acid arachidonic acid (AA) to regulate the release of IL-6 from rat resident peritoneal macrophages (Mø) in vitro. AA (0.5–16 μM) stimulated IL-6 release during a 4 h incubation period in a biphasic manner, with 4 μM AA generating a peak of IL-6 release (3-5-fold). AA (0.5–16 μM) also induced an increasing release of the AA metabolite thromboxane B₂ (TXB₂). The AA-induced release of IL-6 occurred within 1–2 h of incubation, whereas TXB₂ concentrations were elevated within 5 min of AA treatment. The TX synthetase inhibitor CGS 12970 (4.0 μM and 40.0 μM) effectively blocked the generation of TXB₂, but increased prostacyclin (PGI₂) generation and potentiated the release of IL-6. In addition, PGI₂, as well as the PGI₂ agonists iloprost and cicaprost, stimulated IL-6 release from Mø by greater than 5-fold over vehicle-treated basal levels. These data suggest that PGI₂ (but not TXA₂) is involved in AA-induced IL-6 release from peritoneal Mø.     

Dismutase activity of ADP-L-glycero-D-manno-heptose 6-epimerase: evidence for a direct oxidation/reduction mechanism

The first positive evidence for the utilization of a direct C-6' ' oxidation/reduction mechanism by ADP-l-glycero-d-manno-heptose 6-epimerase is reported here. The epimerase (HldD or AGME, formerly RfaD) operates in the biosynthetic pathway of l-glycero-d-manno-heptose, which is a conserved sugar in the core region of lipopolysaccharide (LPS) of Gram-negative bacteria. The stereochemical inversion catalyzed by the epimerase is interesting as it occurs at an "unactivated" stereocenter that lacks an acidic C-H bond, and therefore, a direct deprotonation/reprotonation mechanism cannot be employed. Instead, the epimerase employs a transient oxidation strategy involving a tightly bound NADP(+) cofactor. A recent study ruled out mechanisms involving transient oxidation at C-4' ' and C-7' ' and supported a mechanism that involves an initial oxidation directly at the C-6' ' position to generate a 6' '-keto intermediate (Read, J. A., Ahmed, R. A., Morrison, J. P., Coleman, W. G., Jr., Tanner, M. E. (2004) J. Am. Chem. Soc. 126, 8878-8879). A subsequent nonstereospecific reduction of the ketone intermediate can generate either epimer of the ADP-heptose. In this work, an intermediate analogue containing an aldehyde functionality at C-6' ', ADP-beta-d-manno-hexodialdose, is prepared in order to probe the ability of the enzyme to catalyze redox chemistry at this position. It is found that incubation of the aldehyde with a catalytic amount of the epimerase leads to a dismutation process in which one-half of the material is oxidized to ADP-beta-d-mannuronic acid and the other half is reduced to ADP-beta-d-mannose. Transient reduction of the enzyme-bound NADP(+) was monitored by UV spectroscopy and implicates the cofactor's involvement during catalysis.     

Analysis of the lipopolysaccharide-induced cytostatic activity of macrophages, by the use of synthetic models

Informations on the structural features implicated in the macrophage-dependent cytostatic activity of "lipid A" preparations were obtained by the use of 15 synthetic glycolipids. Four structural requirements were identified: the presence of a reducing glucosamine unit; the presence of a free hydroxyl group on amide-linked 3-hydroxytetradecanoic acids, and the absence of free hydroxyl groups at positions 3 and 6 of the glucosamine. The monosaccharide resembling the reducing unit of the "lipid A backbone," which fulfills these criteria, had the highest cytostatic activity, whereas the compound possessing the substitution pattern of the nonreducing moiety was inactive.     

In vitro collagen fibril assembly in glycerol solution: evidence for a helical cooperative mechanism involving microfibrils

Glycerol inhibits the in vitro self-association of monomeric collagen into fibrils and induces the dissociation of fibrils preassembled from NaBH4-reduced collagen. These effects were investigated in an effort to understand the mechanism of fibril assembly of the protein. In PS buffer (0.03 M NaPi and 0.1 M NaCl, pH 7.0) containing 0.1-1.0 M glycerol, the self-association of type I collagen from calf skin took place only if the protein concentration was above a critical value. This critical protein concentration increased with increasing glycerol concentration. Velocity sedimentation studies showed that below the critical protein concentration and under fibril assembly conditions, the collagen was predominantly in a monomeric state. Electron microscopic examinations revealed that the collagen aggregates formed above the critical concentration consisted mostly of microfibrils of 3-5-nm diameter along with some banded fibrils were found. Collagen treated with pepsin to remove its nonhelical telopeptides also self-associated into microfibrils and fibrils in the presence of glycerol, but the reaction did not exhibit any critical concentration. These results are consistent with a mechanism of in vitro collagen fibril assembly which involves the initial formation of microfibrils through a helical cooperative mechanism. They also suggest that contacts of the nonhelical telopeptides of each collagen with its neighboring molecules provide the necessary negative free energy change for the cooperativity and that subsequent lateral association of the microfibrils leads to banded fibrils.     

Cytostatic properties of a novel compound derived from Penicillium pinophilum: an in vitro study

3-O-Methylfunicone (OMF), a secondary metabolite produced by Penicillium pinophilum, inhibits the in vitro growth of plant pathogenic fungi. This specific property suggested that the compound could be used against other fungal pathogenic activities, including dermatological ones. However, for such applications, toxicological side-effects should be taken into account, in order to prevent other types of risk to mammalian cells. Therefore, investigations were made of the basic toxicity of OMF toward a human tumour cell line. The compound was found to have a cytostatic effect, which represents a counter-indication to its use as a therapeutic agent in dermatology, but suggests that it may have potential as an anti-tumour agent. This study confirmed the validity of in vitro systems for preliminary assays on new compounds, in order to avoid the use of animals in toxicological studies.     

Calcium ion downregulates soluble guanylyl cyclase activity: evidence for a two-metal ion catalytic mechanism

The inhibition of soluble guanylyl cyclase by Ca2+ has been kinetically characterized and the results support a two-metal-ion catalytic mechanism for formation of cGMP. Ca2+ reversibly inhibits both the basal and NO-stimulated forms of bovine lung soluble guanylyl cyclase. Inhibition is independent of the activator identity and concentration, revealing that Ca2+ interacts with a site independent of the heme regulatory site. Inhibition by Ca2+ is competitive with respect to Mg2+ in excess of substrate, with Kis values of 29 +/- 4 and 6.6 +/- 0.6 microM for the basal and activated states, respectively. Ca2+ inhibits noncompetitively with respect to the substrate MgGTP in both activity states. The qualitatively similar inhibition pattern and quantitatively different Ki values between the basal and NO-stimulated states suggest that the Ca2+ binding site undergoes some structural modification upon activation of the enzyme. The competitive nature of Ca2+ inhibition with respect to excess Mg2+ is consistent with a two-metal-ion mechanism for cyclization.     

The inhibition of bovine ceruloplasmin oxidase activity by thiomolybdates in vivo and in vitro: a reversible interaction

The administration of pharmacological doses (greater than 100 mg Mo) of trithiomolybdate or tretrathiomolydbate to ruminants causes a transient apparent decrease in the ceruloplasmin oxidase activity of plasma and a more persistent increase in copper bound to plasma albumin. Sephadex gel-filtration and/or dilution of "inhibited" samples taken from an infused animal or of plasma treated with thiomolybdate in vitro restores activity back to pretreatment levels. The increase in albumin bound copper does not appear to be related to ceruloplasmin breakdown. It is concluded that, contrary to a recent report, the inhibition of ceruloplasmin oxidase activity is reversible and thus unlikely to be of pathological relevance, since circulatory thiomolybdate concentrations in molybdenotic animals are likely to be very low. It is recommended that thiomolybdate preparations used for in vitro and in vivo studies should be carefully purified by Sephadex chromatography.     

Synthesis and in vitro cytostatic activity of 1,2- and 1,3-diacylglycerophosphates of clofarabine

The conjugates of anticancer nucleoside clofarabine [2-chloro-9-(2-deoxy-2-fluoro-β-d-arabinofuranosyl)adenine] with 1,2- and 1,3-diacylglycerophosphates have been prepared by the phosphoramidite method using a combination of 1,1,3,3-tetraisopropyldisiloxane-1,3-diyl protecting group for the sugar moiety of the nucleoside and 2-cyanoethyl protection for the phosphate fragment. Some of the synthesized conjugates exhibited cytostatic activity against HL-60, A-549, MCF-7, and HeLa tumor cell lines.     

Silica toxicity for macrophages in vitro: a new cytotoxicity test.

Soluble factors released from silica-damaged macrophages inhibit proliferation of various haematopoietic cells in long term cultures. The same holds true for damage induced by heat, non-physiological pH, freezing and thawing. This phenomenon is dose-dependent and correlates with the degree of macrophage viability. Thus, a base for measuring the amount of damage to the macrophage is established.     

Plastid division: evidence for a prokaryotically derived mechanism

Plastid division is a critical process in plant cell biology but it is poorly understood. Recent studies combining mutant analysis, gene cloning, and exploitation of genomic resources have revealed that the molecular machinery associated with plastid division is derived evolutionarily from the bacterial cell division apparatus. Comparison of the two processes provides a basis for identifying new components of the plastid division mechanism, but also serves to highlight the differences, not least of which is the nuclear control of the plastid division process.     

Evidence for cytostatic T cell activity in the effector mechanism against syngeneic TMT mammary tumor cells in mice

The effector mechanism of immune spleen cells against syngeneic TMT mammary tumor cells was analyzed in vitro. C3H/He mice were first inoculated with TMT tumor cells, and then the tumors were x-irradiated with 2000 rad 1 wk after the inoculation. Spleen cells from these treated mice inhibited the growth of tumor cells in vitro when assessed by (3H)-TdR incorporation by tumor cells (cytostatic activity). The same spleen cells did not have any cytotoxic activity on TMT tumor cells detected by a 51Cr-release assay. The cytostatic activity was mediated by Lyt-1+23- T cells. The purified T cells alone could not inhibit the growth of tumor cells, but accessory cells were required for the induction of cytostatic T cell activity. The accessory cells were Ia-positive, macrophage-like adherent cells. Furthermore, both T cells and macrophages were also required for the inhibition of tumor growth even after the spleen cells were activated in vitro. These results suggest T cells and macrophages play an important role in the effector mechanism against TMT mammary tumor cells. The mechanism of cytostasis by T cells and macrophages was discussed from the standpoint of the cellular interaction.