Diaminic Carbonates, a New Class of Anti-inflammatory Compounds: Their Biological Characterization and Mode of Action

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Vol. 285, Issue 1, 193-200, April 1998

Diaminic Carbonates, a New Class of Anti-inflammatory Compounds: Their Biological Characterization and Mode of Action

Giuliana Porro, Giorgio Bertolini, M. Antonietta Bonardi, Elena Giovanetti¹, Paola Lento², Flavio Leoni, Daniela Modena, Gianfranco Pavich and Fabrizio Marcucci³

Italfarmaco S.p.A., Centro Ricerche, Milan, Italy

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

Taking advantage of a standard assay on mouse LM cells (murine fibroblast-like cells), we found that several diaminic carbonates,a new class of organic compounds synthesized in our laboratories,were able to inhibit human tumor necrosis factor $alpha$ (huTNF $alpha$ )-inducedcytotoxicity in a dose-dependent manner. Structure-function relationshipstudies indicated precise structural requirements for compoundsbeing active as huTNF $alpha$ inhibitors. ITF1779, one of the most activecompounds in inhibiting huTNF $alpha$ -induced cytotoxicity, was selectedfor further studies. In vitro experiments showed that ITF1779inhibited not only huTNF $alpha$ -induced cytotoxicity on LM cells butalso another response of the same cells, interleukin-1-inducedinterleukin-6 production. Receptor-binding studies performed undernonequilibrium conditions and morphologic evidence of vacuoleformation in cells treated with high concentrations of ITF1779showed that the effects were strikingly similar to those of chloroquine,a lysosomotropic agent. Consistent with a mechanism of actionof diaminic carbonates closely matching that of chloroquine aresome structural similarities between the two classes of compounds,in particular their both being diprotic weak bases. Moreover,ITF1779 was shown to be active in vivo because it afforded protectionagainst lipopolysaccharide-induced shock in mice, a systemic inflammatoryresponse crucially dependent on tumor necrosis factor $alpha$ production.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

Tumor necrosis factor $alpha$ (TNF $alpha$ ) is an inflammatory cytokine that plays a pivotal role in the host defense against pathogens(Echtenacher et al., 1990; Nakano et al., 1990; Smith et al.,1990; Williams et al., 1990). However, in case of chronic or acutesystemic or localized overproduction, TNF $alpha$ has been shown to lead,in conjunction with other mediators of the inflammatory response,to a large number of pathologic conditions. Sepsis syndrome, cachexia,cerebral malaria and rheumatoid arthritis are but a few examplesin which TNF $alpha$ has been shown to play a significant pathogenicrole (Grau et al., 1987; Oliff et al., 1987; Tracey et al., 1986;Brennan et al., 1992). These findings have fostered significantefforts to discover drugs able to inhibit TNF $alpha$ in the hope oftheir having therapeutic application in inflammatory disease statesshown to be crucially dependent on TNF $alpha$ overproduction. Researchactivity along these lines led to the identification of severalcompounds able to inhibit, with different degrees of selectivity,either the production (Moreira et al., 1993; Han et al., 1990;Lee et al., 1994) or the activity of TNF $alpha$ (Alzani et al., 1993;Tracey et al., 1987). Results from clinical trials with anti-huTNF $alpha$ monoclonal antibodies support the idea that approaches aimed atblocking huTNF $alpha$ can lead to significant therapeutic successes(Chikanza and Fernandes, 1996).

In the present report, we describe a class of diaminic carbonates that were synthesized in our laboratories and some membersof which were found to inhibit huTNF $alpha$ -induced cytotoxicity inthe course of a screening program that had been established tofind compounds with anti-huTNF $alpha$ activity. A compound (ITF1779)that scored as one of the most potent in the huTNF $alpha$ cytotoxicityassay was investigated in detail. Results showed that its inhibitoryeffect was not specific for huTNF $alpha$ but rather extended to at leastone other response that has been investigated in the same cellline, IL-1-induced IL-6 production. Moreover, experiments performedto elucidate its mechanism of action allowed us to conclude thatit had effects closely matching those of chloroquine (fig. 1),a lysosomotropic agent (Mackenzie, 1983) that bears some structuralresemblance to diaminic carbonates in being a hydrophobic diamine.In in vivo experiments, ITF1779 was shown to afford significantprotection from lethality against LPS-induced shock in mice, asystemic inflammatory response crucially dependent on TNF $alpha$ production.

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Fig. 1. Structural requirements for diaminic carbonates being optimally active in inhibiting huTNF $alpha$ -induced cytotoxicity. Chloroquine and azaspirane (SK&F-106615) formulas.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Diaminic carbonates. Diaminic carbonates were prepared using a new methodology for the synthesis of both symmetrical and asymmetrical compoundsstarting from the corresponding aminoalcohols (Bertolini, G. etal., manuscript in preparation). All compounds were identifiedby ¹H nuclear magnetic resonance (NMR), ¹³C-NMR, mass spectrometry and infrared spectroscopy, and the purityof each batch was determined by gas chromatography and elementalanalysis. Diaminic carbonates are hygroscopic, stable oil or low-meltingsolid (e.g., ITF1779 melting point = 95-98°C) and are stable forat least 30 days at room temperature in aqueous solution.

Materials. The following drugs and chemicals were used in this study: huTNF $alpha$ (WOC, Vaduz, Liechtenstein), iodinated huTNF $alpha$ (¹²⁵I-huTNF $alpha$ ) (930 µCi/µmol; DuPont NEN, Boston, MA) and MTT, EGTA,AcD and CHX (Sigma Chemical Co., St. Louis, MO).

Cytotoxicity assays. LM cells (murine fibroblast-like cells $---$ ATCC CCL1.2; 1.5 × 10⁴/well) were cultured overnight in 96-well plates (Costar, Cambridge,MA). After 24 h, huTNF $alpha$ was added either alone or in combinationwith the indicated diaminic carbonates. The plates were then incubatedfor 48 h at 37°C. Thereafter, cells were pulsed with 40 µl ofMTT solution (5 mg/ml in PBS) for 4 h at 37°C; medium was thendiscarded, dimethylsulfoxide (200 µl) was added and the O.D. wasread at 570 nm. Percent cytotoxicity was calculated as 100 $-$ (O.D.of LM cells incubated with huTNF $alpha$ /O.D. of LM cells alone) × 100;percent inhibition of huTNF $alpha$ -induced cytotoxicity was calculatedas 100 $-$ [(% cytotoxicity in the presence of the indicated diaminiccarbonates/% cytotoxicity with huTNF $alpha$ alone) × 100]. The indicatedresults of these as well as of all other in vitro assays reportedhere were obtained in representative experiments that were performedat least twice with similar results.

Binding assays. LM cells (1.5 × 10⁵ cells/well) were cultured overnight in 24-well plates (Costar Italia, Milan, Italy); the medium was thendiscarded and the cells incubated with ¹²⁵I-huTNF $alpha$ in the absence or presence of a 100-fold excess of unlabeledhuTNF $alpha$ or diaminic carbonates ITF1779 or ITF1493. Assays wereperformed at 4°C or 37°C and for different incubation times, asindicated. Cells were then washed three times with PBS 0.1% BSA,and cell-bound radioactivity was recovered by solubilization ofcells with 1 N NaOH and measured in a $gamma$ -counter (LKB-Pharmacia,Uppsala, Sweden). Internalized ¹²⁵I-huTNF $alpha$ was measured after treating cells with acidic buffer(0.1 M glycine, pH 3) for 5 min at 4°C and was defined as thefraction that remained cell-associated after this treatment. Tomeasure degradation of ¹²⁵I-huTNF $alpha$ , we treated cell-dissociated ¹²⁵I-huTNF $alpha$ with 10% TCA and, after centrifugation, determined theradioactivity of the TCA-soluble and insoluble fractions. Scatchardplot analyses were performed with the aid of data analysis program(EBDA, Elsevier Science Publishers, Amsterdam, The Netherlands).

IL-1-induced IL-6 production. LM cells (3 × 10⁴ cells/well of 96-well plates) were incubated for 24 h or 48 h with mouse IL-1 $alpha$ (10 ng/ml; Genzyme, Cambridge,MA) in the absence or presence of ITF1779 or ITF1493. At the endof the incubation times, supernatants were harvested and IL-6titers measured by means of a sandwich ELISA (Mouse IL-6 ELISAKit, Genzyme) according to the manufacturer's instructions.

LPS-induced shock. BALB/c female mice (8-12 weeks old, Charles River, Calco, Italy) were injected i.p. with Salmonella enteritidis LPS (5 mg/kg,Sigma). Immediately afterwards, some animals were treated s.c.with the indicated doses of ITF1779. Dexamethasone (Sigma) wasused as a positive control and was administered i.p. 30 min beforeLPS at the dose of 30 mg/kg. Survival was monitored for 7 days.Statistical analysis of survival was performed by the log-ranktest, using the computer software Graph Pad Prism 2.01 (IntuitiveSoftware for Science, San Diego, CA).

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Screening of diaminic carbonates for inhibition of huTNF $alpha$ -induced cytotoxicity. As part of a screening program that had been established in our laboratories to find compounds with anti-huTNF $alpha$ activity,we tested diaminic carbonates, a class of organic compounds synthesizedin our laboratories. The first members of this class were originallysynthesized for the salification of the polyanionic molecule heparinwith positively charged counterion molecules in order to facilitatethe passage of heparin through mucous membranes by neutralizingthe negative charges that it carries (Andriuoli et al., 1990).Several diaminic carbonates were found to be significantly activein inhibiting huTNF $alpha$ -induced cytotoxicity on LM cells, the screeningassay that had been selected to find active compounds. We chosethis assay to identify compounds with huTNF $alpha$ -inhibitory activitybecause of the ease of its execution and because of the possibilityof obtaining a strictly quantitative measurement of TNF activity(Ruff and Gifford, 1981). Table 1 shows the general structuralformula of diaminic carbonates and the individual formulas ofsome active and some inactive compounds of this class. ITF1779,the most active compound that had emerged during the first screening,and ITF1493, an inactive compound, were selected for the studiesreported here. On the basis of the knowledge of the structure-activityrelationship that we acquired by screening the first panel ofdiaminic carbonates, we synthesized and tested a second panel.Altogether, screening of these compounds enabled us to establishprecise structural requirements for diaminic carbonates beingactive as huTNF $alpha$ inhibitors. These are summarized in figure 1.

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TABLE 1
Diaminic carbonates. Chemical structure and anti-huTNF $alpha$ activity
General chemical structure

ITF1779: In vitro activities and mechanism of action. Figure 2 shows the effect of coincubating different doses of huTNF $alpha$ with different doses of ITF1779. ITF1779 inhibited ina dose-dependent manner the cytotoxic activity of huTNF $alpha$ on LMcells. The effect was inversely proportional to the dose of huTNF $alpha$ .

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Fig. 2. Inhibition of huTNF $alpha$ -induced cytotoxicity on LM cells by ITF1779. LM cells were incubated with huTNF $alpha$ alone ( $black-square$ ) or with huTNF $alpha$ and the following doses of ITF1779: ( $square$ ), 2 µM; ( $bullet$ ), 6 µM; ( $open circle$ ), 20 µM; ( $black-lozenge$ ), 60 µM. After 48 h cytotoxicity was measured as described in "Materials and Methods."

Subsequent experiments were performed to clarify the mechanism of action of ITF1779. In a first experiment, ITF1779 was addedto LM cells at the same time as, or at different times after,huTNF $alpha$ . As shown in figure 3, the inhibitory effect of ITF1779was still detectable, though reduced, when it was added 4 h afterhuTNF $alpha$ . At later times it was essentially undetectable.

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Fig. 3. Inhibition of huTNF $alpha$ -induced cytotoxicity on LM cells by ITF1779 added at different times after huTNF $alpha$ . LM cells were incubated with huTNF $alpha$ (3 ng/ml) either alone or with huTNF $alpha$ and ITF1779 (50 µM) added at the same time as huTNF $alpha$ or at different times after huTNF $alpha$ . Then, 48 h after the addition of huTNF $alpha$ , cytotoxicity was measured and the percent inhibition of huTNF $alpha$ -induced cytotoxicity was determined as described in "Materials and Methods."

To determine whether ITF1779 could directly interfere with the interaction between huTNF $alpha$ and TNFR, we tested the abilityof ITF1779 to inhibit the binding of huTNF $alpha$ to LM cells understeady-state conditions (4°C). This assay measures the bindingof huTNF $alpha$ to only one (p55 TNFR) of the two TNFR because huTNF $alpha$ does not interact with the second TNFR (p75 TNFR) expressed onmouse cells (Lewis et al., 1991

). In parallel experiments, wealso tested the effect of ITF1779 on a soluble, recombinant formof the human p55 TNFR. Both experiments yielded negative resultsat all doses tested (data not shown).

These results, which showed that ITF1779 did not interfere with the ligand-receptor interaction, prompted us to check thespecificity of the observed inhibitory effect on huTNF $alpha$ -inducedcytotoxicity. For this purpose we studied another biological responseof LM cells unrelated to the first: IL-1-induced IL-6 production(Akira et al., 1993

). In this experiment we also included ITF1493,which had scored negative in the cytotoxicity assay (see table1). Table 2 shows that ITF1779, but not ITF1493, inhibited thiscellular response in a dose-dependent manner. This inhibitionwas not due to either additive or synergistic toxic effects ofITF1779 and IL-1 on LM cells (data not shown). This result allowedus to conclude that the inhibitory effect was not specific forhuTNF $alpha$ but extended to at least one other LM cell response.

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TABLE 2
Effect of ITF1779 or ITF1493 on IL-1-induced IL-6 production by LM cells^a

Further binding experiments performed with ¹²⁵I-huTNF $alpha$ on LM cells at 37°C were helpful in shedding light on the mechanism underlyingthe previously described inhibitory effects of diaminic carbonateson LM cells. At 37°C, huTNF $alpha$ induces TNFR aggregation (Grazioliet al., 1994

; Pennica et al., 1992

) and subsequent internalization(Tsujimoto et al., 1985

). Experiments performed at this temperaturetherefore make it possible to investigate the fate of huTNF $alpha$ subsequentto the initial interaction with its specific receptors.

Initially, we found that at 37°C ITF1779 induced a significant increase of the binding of ¹²⁵I-huTNF $alpha$ to LM cells (table 3) that was seemingly at odds withthe observed inhibition of the biological response. This increasewas not observed in the presence of ITF1493. The increase wasnot due to enhanced background binding by ITF1779, because coincubationof ¹²⁵I-huTNF $alpha$ , unlabeled huTNF $alpha$ and ITF1779 yielded values of boundcpm similar to those obtained in the absence of ITF1779 (datanot shown). By means of experiments measuring the amount of internalized¹²⁵I-huTNF $alpha$ as determined after cell washings carried out with acidic(pH 3) buffer, we could rule out the increase of ¹²⁵I-huTNF $alpha$ binding being due to enhanced internalization of theligand (table 4). ITF1779 did not alter the ratio between cellsurface-bound and internalized ¹²⁵I-huTNF $alpha$ : 20% to 30% of it remained cell surface-bound, and 70%to 80% was internalized in either the absence or the presenceof ITF1779 or ITF1493.

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TABLE 3
Effect of ITF1779 or ITF1493 on binding of ¹²⁵I-huTNF $alpha$ to LM cells at 37°C^a

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TABLE 4
Effect of ITF1779 or ITF1493 on internalization of ¹²⁵I-huTNF $alpha$ into LM cells at 37°C^a

Scatchard plots from binding experiments performed at 37°C in the absence or presence of 60 µM ITF1779 or ITF1493 indicatedthat in the presence of ITF1779, there was an approximately 4-foldincrease in the number of binding events/cell over the 4-h periodconsidered without any changes in the affinity constants (table5). No significant effect was observed in the presence of ITF1493.

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TABLE 5
Scatchard plots of binding of ¹²⁵I-huTNF $alpha$ , in the absence or presence of ITF1779 or ITF1493, to LM cells at 37°C^a

These results prompted us to investigate whether enhanced binding of ¹²⁵I-huTNF $alpha$ might have been due to increased receptor synthesis orto the unmasking of cryptic plasma membrane TNFR. Both possibilitieswere excluded by subsequent experiments.

Thus, even in conditions where synthesis of TNFR was blocked through the addition of CHX or AcD, ITF1779 increased the bindingof ¹²⁵I-huTNF $alpha$ to LM cells (table 6). On the other hand, no such enhancementwas observed for the binding of ¹²⁵I-huTNF $alpha$ to purified LM cell plasma membranes; this result excludedthe possibility that ITF1779 acted by unmasking cryptic plasmamembrane TNFR (data not shown).

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TABLE 6
Binding of ¹²⁵I-huTNF $alpha$ to LM cells in the absence or presence of ITF1779 or ITF1493. Effect of AcD or CHX

At this point we were left with the possibility that ITF1779 interfered with steps subsequent to the internalization of TNF $alpha$ ,in particular lysosomal degradation (Tsujimoto et al., 1985

).For this purpose, we set up experiments including, as positivecontrol, chloroquine, a lysosomotropic agent (Mackenzie, 1983

)known to interfere with the intracellular handling of internalizedligands in general and of TNF $alpha$ in particular (Tsujimoto et al.,1985

). Thus, LM cells were incubated at 37°C in the absence orpresence of ITF1779, ITF1493 or chloroquine. After removal ofmedium and two washing steps, cells were incubated with ¹²⁵I-huTNF $alpha$ for 1, 6 or 24 h at 37°C, and at the end of each timeperiod, we measured cell surface-bound (fig. 4A), internalized(fig. 4B) and cell-dissociated, degraded ¹²⁵I-huTNF $alpha$ (fig. 4C). Preliminary experiments had shown that ITF1779still inhibited huTNF $alpha$ -induced cytotoxicity under these conditions(data not shown). As can be seen, in contrast to LM cells incubatedwith medium or with ITF1493, samples treated with ITF1779 or chloroquinedid not release degraded ¹²⁵I-huTNF $alpha$ but rather, over time, accumulated progressively increasingamounts of ¹²⁵I-huTNF $alpha$ . These latter experiments suggested that ITF1779 actedthrough a mechanism very similar to that of chloroquine. Furthersubstantiating such similarity was morphologic evidence of vacuoleformation and swelling of LM cells treated with $>=$ 100 µM ITF1779.This was not observed at lower concentrations. Moreover, vacuoleformation was not observed at any dose of ITF1493 tested (datanot shown).

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Fig. 4. Effect of ITF1779 on accumulation and degradation of ¹²⁵I-huTNF $alpha$ . LM cells were incubated overnight at 37°C in the absence ( $black-square$ ) or presence of 60 µM ITF1779 ( $square$ ), 60 µM ITF1493 ( $bullet$ ) or 60 µM chloroquine ( $open circle$ ). After two washing steps, ¹²⁵I-huTNF $alpha$ (6 × 10¹⁰ M) was added for the indicated times in the absence or presence of excess, unlabeled huTNF $alpha$ . Surface-bound (panel A), internalized (panel B) and degraded (panel C) ¹²⁵I-huTNF $alpha$ was then measured as described in "Materials and Methods." Values are indicated as percent of total specifically bound ¹²⁵I-huTNF $alpha$ .

ITF1779: In vivo protection from LPS-induced shock. On the basis of the results obtained in vitro, we investigated potential in vivo effects of ITF1779. Preliminary, acute toxicitystudies showed an LD₅₀ of >400 mg/kg for ITF1779 administereds.c. Thus we selected, for the in vivo studies, doses of ITF1779that allowed indefinite survival of the animals without overtsigns of side effects (3 mg/kg and 10 mg/kg). ITF1779 was studiedfor its capacity to afford protection from LPS-induced shock inmice, a systemic inflammatory response crucially dependent onTNF $alpha$ production (Bone, 1993; Mohler et al., 1994; Tracey et al.,1987; Williams and Summers, 1994). Indeed, as figure 5 shows,ITF1779 at 10 mg/kg significantly increased the survival of treatedanimals (P < .001 vs. LPS alone). At 3 mg/kg the percentage oflong-term survivors was almost twice that in the LPS group, althoughthe difference did not attain statistical significance.

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Fig. 5. Effect of ITF1779 on survival in LPS-induced shock. BALB/c mice (20-30 animals/group) were treated i.p. with LPS and, immediately thereafter after, s.c. with ITF1779 or with saline. Dexamethasone was administered i.p. 30 min before LPS treatment. Results were obtained in three separate experiments. Statistical analysis was performed by the log-rank test: Dexamethasone vs. LPS, P < .001; ITF1779 3 mg/kg vs. LPS, not significant; ITF1779 10 mg/kg vs. LPS, P < .001.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

Diaminic carbonates are a class of organic compounds characterized by the presence of two hydrophobic amines and by the insertion,between the two aminic groups, of a both chemical and enzymaticallylabile site, the carbonate diester (Nassar et al., 1992).

Some of these compounds were found to inhibit, in a dose-dependent manner and with an IC₅₀ in the micromolar range, huTNF $alpha$ -inducedcytotoxicity on LM cells. Because some of these compounds (suchas ITF1779) contain two stereogenic carbon atoms, they are actuallya mixture of three stereoisomers. In the case of ITF1779, theindependent stereoselective synthesis of the three stereoisomersshowed that the enantiomerically pure compounds were as activeas the mixture (data not shown).

Initial experiments indicated that ITF1779 had to be added either at the same time or shortly after huTNF $alpha$ in order to inhibitthe measured biological response. Moreover, inhibition of huTNF $alpha$ cytotoxicity was not a specific effect, because also IL-1-inducedIL-6 production by the same cells was inhibited by ITF1779 butnot by ITF1493, a compound of the same class that is inactivein inhibiting huTNF $alpha$ cytotoxicity. Further experiments aimed atdemonstrating possible effects of active diaminic carbonates onligand binding and post-binding events indicated that ITF1779was essentially inactive in inhibiting the specific binding of¹²⁵I-huTNF $alpha$ to LM cells under steady-state conditions but that itinterfered with events subsequent to initial binding of the ligandand leading to progressive intracellular accumulation of ¹²⁵I-huTNF $alpha$ without releasing degraded, TCA-soluble ¹²⁵I-huTNF $alpha$ . These results were very similar to those obtained inthe same experiments with chloroquine, a lysosomotropic agent(Mackenzie, 1983; De Duve et al., 1974). Moreover, at high concentrationsof ITF1779, we observed extensive vacuole formation and swellingof LM cells, another phenomenon that closely matched the reportedeffects of chloroquine (Estes et al., 1987; Lie and Schofield,1973) and that has been ascribed to sequestration of large quantitiesof cellular membrane within lysosomal vesicles (Mackenzie, 1983;De Duve et al., 1974). Given that chloroquine and, more generally,4-aminoquinolines bear some structural similarities to the diaminiccarbonates described here (both are diprotic weak bases), it isreasonable to assume that, like chloroquine (Mackenzie, 1983),diaminic carbonates become trapped within lysosomes, which causesthe local pH level to exceed the optimal range for acid hydrolasesto perform their digestive functions. This would then lead toinhibition of intracellular degradation of huTNF $alpha$ , as describedin the present experiments. On the other hand, many cellular activitieshave been shown to depend on a functional lysosomal system (Mackenzie,1983). It is therefore not surprising that interfering with ithas resulted in the consistent, reversible inhibition of basalcell work and responsiveness to external stimuli (Hurvitz andHirschhorn, 1965; Goldstein et al., 1975), effects similar tothe inhibition, described here, of huTNF $alpha$ -induced cytotoxicityof LM cells and of IL-1-induced IL-6 production by the same cells.

Notwithstanding the lack of specificity of active diaminic carbonates as regards the inducing stimulus (huTNF $alpha$ or IL-1), duringthe screening of the compounds, we observed precise structuralrequirements for their being active as huTNF $alpha$ inhibitors (table1). In summary, it was found that 1) the diaminic system is crucialfor the measured activity because all monoaminic compounds tested(such as the alcohols formed by hydrolysis of the carbonate diester)were inactive; 2) the presence of the carbonate group is not relevantfor activity but represents a point in which the molecule canbe degraded both chemically and enzymatically, thus avoiding accumulationof the compound, particularly during long-term treatment; 3) thelength of the carbon chain is crucial for good activity (ITF1779vs. ITF2083); 4) the nature of the alkyl chain on nitrogen atomsis very important for activity, and the best results were obtainedin the case of linear, medium-sized alkyl chains such as n-propyl,n-butyl and n-pentyl (ITF1779 vs. ITF2109); 5) the presence ofbranching near the carbonate group is very important for activity(ITF1779 vs. ITF2002). We observed higher activity for those compoundsthat have a small alkyl group such as methyl (e.g., ITF1779),ethyl and n-propyl near the carbonate.

In vivo studies performed with ITF1779 suggest that active diaminic carbonates can be therapeutically useful. In fact, ITF1779afforded protection from LPS-induced shock, a systemic inflammatoryresponse the pathogenesis of which is crucially dependent on TNFproduction (Bone, 1993; Mohler et al., 1994; Tracey et al., 1987;Williams and Summers, 1994). More recent, preliminary results(F. Leoni, G. Bertolini, F. Di Pierro, unpublished observations)in other in vivo models of inflammatory responses confirm thetherapeutic efficacy of ITF1779.

The present results could also be relevant for other classes of molecules of pharmacological interest that bear some structuralsimilarities to the diaminic carbonates reported here. The previouslymentioned chloroquine is, together with hydroxychloroquine, atherapeutically useful agent in some conditions of chronic inflammation,such as rheumatoid arthritis and systemic lupus erythematosus(Fowler et al., 1984; Ten Wolde et al., 1996; O'Dell et al., 1996).As previously mentioned, chloroquine (fig. 1) and, more generally,molecules of the 4-aminoquinoline class of compounds have a generalformula that, in some essential features, resembles that of diaminiccarbonates. Indeed, although chloroquine contains a heterocyclicmoiety, this compound can also be considered a hydrophobic diaminelike our diaminic carbonates. The same is true of azaspiranes(fig. 1), a recently described new class of compounds some membersof which have been shown to possess remarkable therapeutic activityin animal models of rheumatoid arthritis (Badger and Swift, 1993;Badger and Wright, 1995). Azaspiranes and diaminic carbonatesare very similar; both are alkylic hydrophobic diamines. It hasbeen suggested that the anti-inflammatory effects of active azaspiranesare due to induction of suppressor cells (Badger and Swift, 1993).On the basis of the present results, it may be worth while toreinvestigate the mechanism of action of these interesting molecules.If the observations on diaminic carbonates reported in the presentpaper can indeed be extended to these classes of molecules, thenit might be tempting to speculate that their mechanism of actiondepends largely on a similar structural backbone that allows themto act as lysosomotropic, diprotic weak bases. However, althoughthis structural motif might be necessary to endow them with biologicalactivity, it is clearly not sufficient for this purpose, as shownby our structure-function relationship studies with diaminic carbonates.The molecular bases that might help explain why the presence ofdiscrete, chemical substituents is necessary to the describedeffects are at present unclear. Preliminary results (F. Leoni,G. Bertolini, F. DiPierro, unpublished observations) suggest thatthese structural requirements vary according to the target cellthat is investigated. Further elucidation of these issues willbe helpful in optimizing the therapeutic potential of diaminiccarbonates, 4-aminoquinolines and, perhaps, other classes of moleculesthat may work through a similar mechanism of action.

	Acknowledgments

We thank Dr. Pietro Ghezzi for helpful suggestions and discussions and Daniela Bretto for technical support.

	Footnotes

Accepted for publication December 16, 1997.

Received for publication April 7, 1997.

¹ Present address: Neurology Dept., University of California, San Francisco, CA.

² Present address: Pathology Dept., Istituto Europeo di Oncologia, Via Ripamonti 435, Milan, Italy.

³ Present address: C.E.L., 60 Bd Melesherbes, Paris, F-5008, France.

Send reprint requests to: Daniela Modena, Centro Ricerche Italfarmaco S.p.A., Via dei Lavoratori, 54, 20092 $---$ Cinisello Balsamo (MI), Italy

	Abbreviations

TNF $alpha$ , tumor necrosis factor $alpha$ ; huTNF $alpha$ , human tumor necrosis factor $alpha$ ; IL-1, interleukin-1; IL-6, interleukin-6; LPS, lipopolysaccharide; MTT, 3-(4-5-dimethyl 2-thiazolyl)-2-5 diphenyl tetrazolium bromide; AcD, actinomycin D; CHX, cycloheximide; PBS, phosphate-buffered saline; BSA, bovine serum albumin; TNFR, TNF receptor(s); TCA, trichloroacetic acid; ¹²⁵I-huTNF $alpha$ , iodinated huTNF $alpha$ .

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