Mechanisms of Intracellular Killing of Rickettsia conorii in Infected Human Endothelial Cells, Hepatocytes, and Macrophages

doi:10.1128/IAI.68.12.6729-6736.2000

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Infection and Immunity, December 2000, p. 6729-6736, Vol. 68, No. 12
0019-9567/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Mechanisms of Intracellular Killing of Rickettsia conorii in Infected Human Endothelial Cells, Hepatocytes, and Macrophages

Hui-Min Feng and David H. Walker^*

Department of Pathology and WHO Collaborating Center for Tropical Diseases, University of Texas Medical Branch, Galveston, Texas

Received 27 April 2000/Returned for modification 14 June 2000/Accepted 23 August 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The mechanism of killing of obligately intracellular Rickettsia conorii within human target cells, mainly endothelium and,to a lesser extent, macrophages and hepatocytes, has not beendetermined. It has been a controversial issue as to whether ornot human cells produce nitric oxide. AKN-1 cells (human hepatocytes)stimulated by gamma interferon, tumor necrosis factor alpha, interleukin1 $beta$ , and RANTES (regulated by activation, normal T-cell-expressedand -secreted chemokine) killed intracellular rickettsiae by anitric oxide-dependent mechanism. Human umbilical vein endothelialcells (HUVECs), when stimulated with the same concentrations ofcytokines and RANTES, differed in their capacity to kill rickettsiaeby a nitric oxide-dependent mechanism and in the quantity of nitricoxide synthesized. Hydrogen peroxide-dependent intracellular killingof R. conorii was demonstrated in HUVECs, THP-1 cells (human macrophages),and human peripheral blood monocytes activated with the cytokines.Rickettsial killing in the human macrophage cell line was alsomediated by a limitation of the availability of tryptophan inassociation with the expression of the tryptophan-degrading enzymeindoleamine-2,3-dioxygenase. The rates of survival of all of thecell types investigated under the conditions of activation andinfection in these experiments indicated that death of the hostcells was not the explanation for the control of rickettsial infection.This finding represents the first demonstration that activatedhuman hepatocytes and, in some cases, endothelium can kill intracellularpathogens via nitric oxide and that RANTES plays a role in immunityto rickettsiae. Human cells are capable of controlling rickettsialinfections intracellularly, the most relevant location in theseinfections, by one or a combination of three mechanisms involvingnitric oxide synthesis, hydrogen peroxide production, and tryptophandegradation.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Among spotted fever group (SFG) rickettsiae, six species are closely related genetically and cause similar clinical and pathologicmanifestations with overlapping spectra of severity. The orderof decreasing overall severity is Rickettsia rickettsii, R. conorii,and R. sibirica. At the less severe end of the spectrum, R. japonica,R. africae, and R. honei have not been documented to cause a fataloutcome. R. akari and R. australis are SFG rickettsiae substantiallymore distantly related to this cluster of six SFG rickettsialpathogens (30, 31, 40). The cell wall of each of these organismscontains the major, immunodominant antigens: rickettsial outermembrane proteins A and B and nonendotoxic lipopolysaccharide(45). R. conorii and R. rickettsii are typical SFG rickettsiae,small, obligately intracellular, gram-negative bacteria that attachto a host cell receptor via one or more adhesins, including rickettsialouter membrane protein A (20). The rickettsiae induce internalizationby phagocytosis in association with phospholipase A₂ activity,apparently of rickettsial origin, and escape from the phagosomeinto the cytosol by an unidentified mechanism (39, 41, 51,54). In the cytosol, R. conorii stimulates the polymerizationof host cell F actin, which propels the bacterium through thecytoplasm and across the cell membrane into the adjacent cellor extracellular space (14, 42).

Boutonneuse fever caused by R. conorii is a classic SFG rickettsiosis transmitted to humans by tick bite inoculation of rickettsiaeinto the skin. Proliferation of rickettsiae in the inoculationsite endothelial network results in focal dermal and epidermalnecrosis, an eschar or tache noire (49). Rickettsiae spreadvia lymphatic vessels to the regional lymph nodes, resulting inlymphadenopathy, and via the bloodstream to the lungs, brain,liver, kidneys, heart, spleen, and skin (47). The target cellsthat have been identified for humans are mainly endothelium and,to a lesser extent, macrophages (47). A mouse model of R. conoriiinfection mimics the visceral pathologic lesions and distributionof rickettsiae in the tissues of human boutonneuse fever and RockyMountain spotted fever (51). In the mouse model, R. conoriiis observed not only in endothelial cells and macrophages butalso in hepatocytes. The murine hepatic lesions resemble thoseobserved in human R. conorii infection (52).

In mouse and guinea pig models of R. conorii infection, rickettsiae are killed within the cytoplasm of the target cells ofinfection, namely, endothelium, macrophages, and hepatocytes (51,53). In infected mice and in mouse endothelial cell cultures,intracellular rickettsicidal activity is mediated by the stimulationof inducible synthesis of nitric oxide by the combination of tumornecrosis factor alpha (TNF- $alpha$ ) and gamma interferon (IFN- $gamma$ ) (8,50). This study was undertaken to evaluate the ability of targetcells of R. conorii in boutonneuse fever $---$ human endothelial cells,macrophages, and hepatocytes $---$ to kill rickettsiae residing in thecytosol upon cytokine and chemokine activation. Because cytokinesalone do not trigger nitric oxide production, the report thatRANTES regulated by activation, normal T-cell-expressed and -secretedchemokine) could induce nitric oxide production by human macrophagesled us to investigate whether this chemokine could play a rolein the induction of nitric oxide synthesis by human endothelialcells and hepatocytes (44). The roles of three potential antirickettsialmechanisms were evaluated: (i) nitric oxide derived via induciblenitric oxide synthase (iNOS), (ii) production of the reactiveoxygen species hydrogen peroxide, and (iii) tryptophan degradationvia indoleamine-2,3-dioxygenase(IDO).

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Rickettsia. R. conorii (Malish 7 strain), an isolate that was obtained from a patient in South Africa and that was subsequently passagedan unknown number of times in the yolk sac of embryonated chickeneggs, was obtained from the American Type Culture Collection (ATCC;Manassas, Va.; catalog no. VR-613). In our laboratory, the organismwas plaque purified and had the following passage history: 39passages in yolk sac of embryonated chicken eggs and 4 passagesin Verocells.

The organism retains virulence in humans, as demonstrated by the development of inoculation site lesions, fever, and systemicsymptoms in two experimentally infected volunteers who had givenInstitutional Review Board-approved informed consent. The stock,aliquots of a 10% suspension of infected yolk sac containing 4× 10⁶ PFU per ml, was stored at $-$ 70°C.

Cell cultures. Pools of human umbilical vein endothelial cells (HUVECs) were purchased from Clonetics (San Diego, Calif.). Other HUVEC cultureswere established from individual or pooled human umbilical cordsas described previously (46). The growth medium was EGM-2 (Clonetics).The cells were subcultured when the monolayer became confluent,two or three times per week. In this study, the cells were usedbetween passages 3 and7.

AKN-1 cells, a human hepatocyte cell line established from wedge sections of normal liver, were a gift from Andreas K. Nussler(University of Ulm, Ulm, Germany) (24). The growth medium wasan equal mixture of Ham F-12 and Williams Medium E (both fromGibco) supplemented with 22.7 mM sodium bicarbonate, 0.8 mg offatty acid-free albumin per ml, 65 µM ethanolamine, 7.18 µM linoleicacid, 7 mM glucose, 0.4 mM sodium pyruvate, 0.1 mM ascorbic acid,15 mM HEPES, 5 µg of insulin per ml, 5 µg of transferrin per ml,5 µg of selenious acid per ml, and 10⁷ M dexamethasone. The cells were subcultured twiceweekly.

THP-1 cells, a human monocytic cell line derived from the peripheral blood of a patient with acute monocytic leukemia, werepurchased from ATCC (catalog no. TIB 202). The cells were grownin Dulbecco's minimal essential medium containing 10% bovine calfserum (BCS) and were subcultured two or three times perweek.

Human monocytes were prepared from the peripheral blood of four healthy donors. The white blood cells were separated from15 to 30 ml of blood by density gradient centrifugation in Ficoll-Paque(Amersham Pharmacia Biotech, Uppsala, Sweden). The monocytes wereisolated by using C14 magnetic microbeads (Miltesivi Biotech,Auburn, Calif.) according to the manufacturer's instructions.The monocytes were adjusted to concentrations of 0.5 × 10⁶ to 1.0 × 10⁶/ml according to the yield from eachdonor.

Reagents. Human recombinant TNF- $alpha$ was purchased from Boehringer Mannheim Biochemicals (Cambridge, Mass.). RANTES and N^G-monomethyl-L-arginine (N^GMMLA) were obtained from R&D Systems, Inc. (Minneapolis, Minn.),and Calbiochem-Novabiochem Corp. (La Jolla, Calif.), respectively.Human recombinant IFN- $gamma$ and interleukin 1 $beta$ (IL-1 $beta$ ) were purchasedfrom Genzyme (Cambridge, Mass.), and catalase and L-tryptophanwere purchased from Sigma Chemical Company (St. Louis, Mo.).

Experimental design. The monolayers of HUVECs, AKN-1, THP-1, or human peripheral blood monocyte cells cultivated in 24-well plates were treatedwith RANTES at 500 ng/ml and either 2,000 U of human recombinantTNF- $alpha$ per ml, 1,000 U of recombinant human IFN- $gamma$ per ml, and 100U of recombinant human IL-1 $beta$ per ml or one-half or one-fourththese doses overnight at 37°C in an atmosphere containing 5% CO₂.Then, the treated cells were infected with rickettsiae to evaluatethe antirickettsial activity associated with nitric oxide synthesis.Similar studies were performed without RANTES to evaluate theantirickettsial effects associated with the production of hydrogenperoxide and with the limitation of the availability of tryptophanby IDO activity. In preliminary studies, the effect of addingRANTES was evaluated and shown not to influence the results ofhydrogen peroxide production or IDO activity in AKN-1 and THP-1cells. N^GMMLA (1 mM), catalase (100 µM), and L-tryptophan (80 µg/ml) wasadded to each cell type for the determination of the effects ofnitric oxide synthesis, hydrogen peroxide production, and tryptophanlimitation,respectively.

Renografin (Bracco Diagnostic Inc., Princeton, N.Y.)-purified R. conorii was inoculated at multiplicities of infection of0.3 or 0.6 into HUVECs and 0.12 into AKN-1 cells, THP-1 cells,and human peripheral blood monocytes. The plates were centrifugedat 770 × g for 10 min to increase the attachment of the rickettsiaeto the cells. The infected cells were incubated at 37°C for 2to 3 days. The cells were scraped from the wells and centrifugedat 440 × g for 10 min. The supernatant was saved for assay ofthe nitrite level. The pellets were suspended in 3 ml of Eagle'sminimum essential medium (EMEM; Gibco) containing 1% BCS and thensonicated for 40 s (Braun-Sonic 2000 Ultrasonicator; UltrasonicPower Corp., Freeport, Ill.) at a power of 28 W to release theintracellular rickettsiae. After centrifugation at 440 × g for10 min, serial 10-fold dilutions were made of the supernatantscontaining the released rickettsiae; 0.2 ml of each dilution wasadded in duplicate to Vero cell monolayers in 24-well plates forplaque assay of the infectious rickettsial content (51). After2 h of incubation at 37°C, 0.5% agarose in EMEM containing 1%BCS and cycloheximide (final concentration, 1 µg/ml) was added.Three days later, the plaques were counted under an invertedmicroscope.

Nitrite level. One hundred microliters of supernatant from each well was divided into aliqouts, which were placed in 96-well U-bottom plates.One hundred microliters of Griess reagent was added per well (13).After incubation at room temperature for 15 to 20 min, the opticaldensities were measured at 540 nm with an enzyme-linked immunosorbentassay reader (Bio-TEK Instruments, Inc., Winooski, Vt.).

RT-PCR. RNA was extracted with UltraspecRNA (BiotecX, Houston, Tex.) from cells that had been infected with rickettsiae and treatedwith cytokines and with or without RANTES or that were uninfectedand uninduced. Reverse transcription (RT)-PCR was performed accordingto the instructions of the manufacturer of the 5' rapid amplificationof cDNA ends (RACE) system (Gibco). The human iNOS primers were5'CTG TCC TTG GAA ATT TCT GTT3' and 5'TGG CCA GAT GTT CCT CTATT3'. The PCR program was 95°C for 30 s, 57°C for 30 s, and 72°Cfor 75 s for 35 cycles, followed by a final extension at 72°Cfor 7 min. The iNOS PCR product was 488 bplong.

The human IDO primers were as follows: forward primer, 5'TTC TCC GGC CAC CTG TTT TCA TAG T3', and reverse primer, 5'TAG TCTGCT CCT CTG GTG CCC CCT C3' (328-bp product). Amplification ofDNA by PCR was performed as follows: 94°C for 30 s, 55°C for 30s, and 72°C for 1 min for 35 cycles plus extension at 72°C for7 min. Primers for the glyceraldehyde-3-phosphate dehydrogenase(G3PDH) housekeeping gene (450-bp product) were obtained fromClontech Laboratory, Inc. (Palo Alto, Calif.). The PCR productswere detected after separation by electrophoresis in a 1.5% agarosegel and staining with ethidiumbromide.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Human cells were observed to use different pathways singly or in combination to control the growth and survival of intracellularrickettsiae. In R. conorii infection, three mechanisms were verifiedas having a role in the intracellular killing of rickettsiae byone or more of the host celltypes.

Effect of nitric oxide production on rickettsial survival. Five different pooled samples and one single-donor-derived sample of R. conorii-infected endothelial cells (HUVECs) stimulatedwith cytokines (TNF- $alpha$ , IFN- $gamma$ , and IL-1 $beta$ ) and a chemokine (RANTES)have been tested. One pool of HUVECs produced a high level ofnitric oxide (measured as a nitrite level of 31.1 ± 1.1 µM) [valueis mean ± standard deviation]). This response was dose dependentand required all of the stimulating proteins. When the cytokineconcentrations were reduced from 2,000 U of TNF- $alpha$ per ml, 1,000U of IFN- $gamma$ per ml, and 100 U of IL-1 $beta$ per ml to half these doses,the nitrite level decreased to 13.2 ± 1.4 µM (Fig. 1). This nitricoxide production was inhibited by the addition to the culturesof the arginine analogue N^GMMLA, an inhibitor of iNOS. The HUVECs were very sensitive tothe effects of high-dose cytokines and RANTES, with substantialendothelial cell death.

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FIG. 1. Concentration of nitric oxide produced by R. conorii-infected HUVECs stimulated by the cytokines TNF- $alpha$ at 2,000 U/ml, IFN- $gamma$ at 1,000 U/ml, and IL-1 $beta$ at 100 U/ml ( $black-square$ ) or TNF- $alpha$ at 1,000 U/ml, IFN- $gamma$ at 500 U/ml, and IL-1 $beta$ at 50 U/ml (

). The cultures of cells treated with cytokines, RANTES, and N^GMMLA are indicated below the pairs of bars representing the higher and lower doses of cytokines.

, cells infected with R. conorii and receiving no treatment. Nitric oxide was measured as the concentration of nitrite and expressed as the mean and standard deviation.

To differentiate whether the decrease in rickettsial survival was due to the direct effect of nitric oxide or was indirect,owing to death of the HUVECs associated with the production ofnitric oxide, serial experiments were performed. A dose and acombination of chemokine and cytokines that resulted in nitricoxide production without reduced survival of the endothelial cellswere sought. After senescence of the pooled HUVECs, a fresh HUVECculture was established from a single umbilical cord. When thesecells were treated with 500 U of TNF- $alpha$ per ml, 250 U of IFN- $gamma$ per ml, 25 U of IL-1 $beta$ per ml, and 500 ng of RANTES per ml, a lowlevel of nitric oxide (3 µM nitrite) was induced. N^GMMLA at a concentration of 1 mM inhibited 57% of the nitric oxideproduction by these cells (P < 0.05). These cytokine- and chemokine-treatedHUVECs showed strong antirickettsial activity that was abrogatedby the iNOS inhibitor N^GMMLA, confirming the importance of the effect of nitric oxideunder the conditions of these experiments (Fig. 2A). The survivalof these HUVECs was not affected adversely by cytokine and chemokineactivation and nitric oxide production (Fig. 2B). These resultsindicate that the nitric oxide produced by HUVECs acted as anintracellular rickettsicidal mechanism that was not caused bydestruction of the host cells. The other four pools of HUVECsdid not produce detectable (less than 1 µM) nitric oxide wheninduced by cytokines and RANTES.

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FIG. 2. Cellular content of infectious rickettsiae measured as PFU (A) and survival of R. conorii-infected HUVECs determined by evaluation of 100 cells by trypan blue dye exclusion (B) after treatment with TNF- $alpha$ (500 U/ml), IFN- $gamma$ (250 U/ml), IL-1 $beta$ (25 U/ml), and RANTES (500 ng/ml), with or without N^GMMLA. Bars: 1, R. conorii-infected cells treated with cytokines and RANTES; 2, R. conorii-infected, cytokine- and chemokine-treated cells exposed to N^GMMLA; 3, untreated R. conorii-infected cells. The mean and standard deviation for three repeated experiments show the features of the nitric oxide-dependent intracellular rickettsial killing mechanism.

The human hepatocyte cell line AKN-1 produced nitric oxide when it was induced by TNF- $alpha$ , IFN- $gamma$ , IL-1 $beta$ , and RANTES (Fig. 3A).The inducible nitric oxide production by AKN-1 cells was a significantrickettsicidal mechanism and did not adversely affect the survivalof the hepatocytes (Fig. 3B and C). RT-PCR using iNOS primersrevealed that the AKN-1 human hepatocytes had expressed detectablemRNA of iNOS 12 h after induction by the cytokines and chemokine(Fig. 4). Infected, uninduced cells did not express mRNA of iNOS(data not shown).

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FIG. 3. Nitric oxide production measured as the concentration of nitrite (A), cellular content of infectious rickettsiae measured as PFU (B), and survival of R. conorii-infected human hepatocytes (AKN-1 cells) determined by trypan blue dye exclusion (C) after treatment with TNF- $alpha$ (2,000 U/ml), IFN- $gamma$ (1,000 U/ml), IL-1 $beta$ (100 U/ml), and RANTES (500 ng/ml), with or without N^GMMLA (1 mM). Bars: 1, R. conorii-infected hepatocytes treated with cytokines and RANTES; 2, R. conorii-infected hepatocytes treated with cytokines, RANTES, and N^GMMLA; 3, untreated R. conorii-infected hepatocytes; 4, uninfected hepatocytes exposed to medium only. The mean and standard deviation for three repeated experiments show the features of the nitric oxide-dependent intracellular rickettsial killing mechanism. Cytokine- and chemokine-activated, infected hepatocytes produced more nitric oxide than similar cultures treated with N^GMMLA (P < 0.001) and than untreated, R. conorii-infected hepatocytes (P = 0.019). Cytokine- and chemokine-activated, infected hepatocytes contained fewer R. conorii than similar cultures treated with N^GMMLA (P = 0.003) and than untreated, R. conorii-infected hepatocytes (P = 0.004).

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FIG. 4. Expression of mRNA of iNOS by human cells induced with cytokines and RANTES, as determined by RT-PCR yielding the expected 488-bp product. (Top panel) Lane 1, markers; lane 2, R. conorii-infected, induced AKN-1 hepatocytes; lane 3, uninfected, induced AKN-1 hepatocytes; lane 4, infected, uninduced AKN-1 hepatocytes; lane 5, water control. (Bottom panel) RT-PCR products of mRNA extracts of G3PDH.

Nitric oxide production was not the rickettsicidal mechanism of the human monocytic cell line THP-1 or the monocytes fromhuman peripheral blood. The combination of cytokines and RANTESdid not stimulate nitric oxide production in these cells. Thequantities of rickettsiae in the treated cells were not influencedby the addition of the nitric oxide synthesis inhibitor N^GMMLA, another indication that nitric oxide was not an antirickettsialmechanism in THP-1 cells or human peripheral blood monocytes underthese conditions (data notshown).

Role of the production of hydrogen peroxide by activated endothelial cells and macrophages in the intracellular killing of R. conorii. Hydrogen peroxide-dependent intracellular killing of R. conorii was demonstrated in HUVECs and THP-1 cells stimulated withcytokines only. Human peripheral blood monocytes were stimulatedwith both cytokines and RANTES. In three repeated experiments,catalase (100 µM) was added to inhibit the effects of hydrogenperoxide; the quantities of viable R. conorii increased 3.8-foldin HUVECs, 2-fold in THP-1 cells, and 10-fold in human peripheralblood monocytes (Fig. 5). In the AKN-1 hepatocyte cell line, hydrogenperoxide did not appear to function as an intracellular rickettsicidalmechanism because there was no change in the content of infectiousrickettsiae in cells after the addition of catalase.

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FIG. 5. Infectious rickettsial content measured as PFU (A) and percent survival (B) for HUVECs infected with R. conorii; infectious rickettsial content measured as PFU (C) and percent survival (D) for THP-1 cells infected with R. conorii; and infectious content measured as PFU (E) and percent survival (F) for human peripheral blood monocytes infected with R. conorii. HUVECs were either treated with TNF- $alpha$ (500 U/ml), IFN- $gamma$ (250 U/ml), and IL-1 $beta$ (25 U/ml) or not treated. THP-1 cells were either treated with TNF- $alpha$ (2,000 U/ml), IFN- $gamma$ (1,000 U/ml), and IL-1 $beta$ (100 U/ml) or not treated. Human peripheral blood monocytes were either treated with cytokines and RANTES or not treated. Catalase was added to infected, cytokine-treated HUVECs, THP-1 cells, and human peripheral blood monocytes to determine the antirickettsial role of H₂O₂. Bars: 1, R. conorii-infected cells treated with cytokines; 2, R. conorii-infected cells treated with cytokines and catalase; 3, untreated R. conorii-infected cells. The results are expressed as the mean and standard deviation for three repeated experiments. Cytokine-activated, R. conorii-infected HUVECs contained fewer R. conorii than similarly activated, infected cells treated with catalase (P = 0.047) and than untreated, infected cells (P < 0.001). Cytokine-activated, R. conorii-infected THP-1 macrophages contained fewer R. conorii than similarly activated, infected cells treated with catalase (P = 0.002) and than untreated, infected cells (P = 0.006). Cytokine- and RANTES-activated, R. conorii-infected human peripheral blood monocytes contained fewer R. conorii than similarly activated, infected cells treated with catalase (P < 0.001) and than untreated, infected cells (P < 0.001).

Role of L-tryptophan depletion in the intracellular killing of R. conorii. mRNA for IDO was present in THP-1 cells activated by cytokines (Fig. 6). This enzyme degrades L-tryptophan into N-formylkynurenineand kynurenine and depletes intracellular L-tryptophan pools,resulting in tryptophan starvation of intracellular parasites.Rickettsial growth was directly influenced by the L-tryptophanlimitation in THP-1 cells (Fig. 7). In these cells, inhibitionof rickettsial survival by activation with TNF- $alpha$ , IFN- $gamma$ , and IL-1 $beta$ was partially reversed by supplementation of the medium with 80µg of L-tryptophan per ml.

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FIG. 6. Expression of mRNA of IDO by human cells induced by cytokines, as determined by RT-PCR yielding the expected 328-bp product. (Top panel) Lane 1, markers; lane 2, R. conorii-infected, induced THP-1 macrophages; lane 3, uninfected, uninduced THP-1 macrophages. (Bottom panel) RT-PCR products of mRNA extracts of G3PDH.

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FIG. 7. Rickettsicidal effect of tryptophan limitation in human macrophages (THP-1 cells) treated with TNF- $alpha$ (2,000 U/ml), IFN- $gamma$ (1,000 U/ml), and IL-1 $beta$ (100 U/ml), as demonstrated by supplementation with 80 µg of L-tryptophan per ml. Bars: 1, rickettsia-infected, cytokine-treated cells; 2, rickettsia-infected, cytokine-treated cells supplemented with L-tryptophan; 3, untreated, rickettsia-infected cells. (A) Infectious rickettsial content (PFU). (B) Percent survival of cells. The results represent the mean and standard deviation for three repeated experiments.

In HUVECs, AKN-1 cells, and human peripheral blood monocytes, L-tryptophan starvation was not a major cause of rickettsicidalactivity. The addition of L-tryptophan to cytokine- and chemokine-treatedHUVECs, AKN-1 cells, and human peripheral blood monocytes didnot result in increased quantities of viable R. conorii (datanotshown).

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

A high proportion of humans recover from Rocky Mountain spotted fever (75 to 80% in the preantibiotic era) and boutonneusefever (95 to 99% in the contemporary period). The antimicrobialagents currently used are bacteriostatic rather than bactericidal,indicating that they merely slow bacterial growth as the hostdefenses, including the immune system, eliminate the rickettsiae.Survivors are immune toreinfection.

Immunity to rickettsiae involves complex interactions of CD4 and CD8 T lymphocytes, macrophages, natural killer cells, B lymphocytes,antibodies, cytokines, and chemokines (6, 8, 9, 11,17, 18, 19, 22, 28, 29, 48, 50, 55). Animalmodels have provided substantial information regarding some ofthese immune mechanisms against Rickettsia species, indicatingthat cellular mechanisms are of paramount importance, particularlyT lymphocytes and the cytokines TNF- $alpha$ and IFN- $gamma$ (8, 9, 17,22, 50). In animals studied over the course of infection,the quantities of morphologically intact rickettsiae increaseover a period of days during the incubation period and the peakof the illness (51, 53). Then, the intracellular quantitiesof rickettsiae decrease, and finally they are no longer detectableby immunohistochemical analysis or cultivation. The disappearanceof the rickettsiae is associated with the appearance of fragmentsof rickettsial antigens that are dispersed as pieces smaller thanthe morphologically intact organisms and as large aggregates inthe host cell cytoplasm. Autophagy of rickettsiae, morphologicallyevident death of rickettsiae, and phagolysosomal aggregation ofdead rickettsiae have been observed in vivo and in cytokine-activatedmurine endothelial cells (8, 50, 51). Thus, the principalantirickettsial immune mechanism in mice appears to be intracellularkilling within the cytoplasm of the target cell by a cytokine-dependent,nitric oxide-dependent mechanism(s) (8, 10, 43, 50).

The data are less extensive for human infection. At sites of infection, where the control of rickettsial growth occurs, humantissues are characterized by perivascular infiltration mainlyby macrophages and lymphocytes, particularly CD4 and CD8 T lymphocytes(15, 49). The role of iNOS in human defenses against infectiousdiseases has been controversial. Nicholson et al. detected iNOSantigen and mRNA in human alveolar macrophages from patients withactive tuberculosis (23), and Rich et al. showed individualvariation in the production of nitric oxide by macrophages fromhealthy human subjects after stimulation of the cells by infectionwith Mycobacterium tuberculosis (27). Monocytes from these subjectsconstitutively expressed iNOS mRNA, the levels of which did notincrease, and produced little or no nitric oxide when stimulatedwith M. tuberculosis. Stimulated alveolar macrophages from differentsubjects showed low (mean, 4 µM nitrite), moderate (mean, 56 µMnitrite), or high (mean, 502 µM nitrite) levels of productionof nitric oxide, which was diminished by iNOS inhibitors. Stimulatedalveolar macrophages expressed larger amounts of iNOS mRNA andprotein. Mycobacterial growth was not significantly increasedby the iNOS inhibitors but was greater in low-nitric-oxide producersthan in moderate-nitric-oxide producers. Also, primary human monocytesactivated by RANTES, monocyte inflammatory protein 1 $alpha$ (MIP-1 $alpha$ ),or MIP-1 $beta$ killed intracellular Trypanosoma cruzi via the iNOS-dependentproduction of nitric oxide (44). Furthermore, human epithelialcell lines activated by human IFN- $gamma$ and TNF- $alpha$ and bacterial lipopolysaccharidecontrolled the survival of intracellular Chlamydia trachomatisby a combination of mechanisms, including iNOS activity, tryptophandegradation, and iron sequestration (16).

Indeed, human cells have been demonstrated to kill or control the growth of intracellular organisms by several mechanisms.Pfefferkorn reported in 1984 that human fibroblasts activatedby IFN- $gamma$ killed Toxoplasma gondii by induction of host cell degradationof tryptophan to kynurenine and formylkynurenine (25). Thismechanism was subsequently extended to other cell types, particularlyhuman monocytes or macrophages and epithelial cells, and to otherorganisms, e.g., C. trachomatis, C. psittaci, and Legionella pneumophila(3, 4, 12, 26, 36). The microbicidal activity wasshown to be mediated by induction of the catabolic enzyme IDOand to be stimulated under certain conditions by TNF- $alpha$ , sometimesin synergy with IFN- $gamma$ or IFN- $beta$ (35, 37). For the human laryngealcarcinoma epithelial cell line HEp-2, of course not a naturaltarget of rickettsial infection, Manor and Sarov demonstratedin 1990 the principle that human cells activated synergisticallyby TNF- $alpha$ and IFN- $gamma$ can restrict the survival of intracellularR. conorii by a tryptophan-limiting mechanism (21).

The long-standing goal of understanding the mechanisms by which rickettsiae are eliminated from infected humans is substantiallyadvanced by the present report. The ability of infected humantarget cells activated by cytokines, in some situations in associationwith the chemokine RANTES, to inhibit the survival of intracellularR. conorii was mediated by nitric oxide-dependent, H₂O₂-dependent,and IDO-dependent mechanisms. These data confirm the conclusionfrom experimental animal and mouse cell culture studies that cytokine-activatediNOS-dependent rickettsicidal activity is consistently an importantmechanism in human immunity to rickettsiae only in hepatocytesactivated by cytokines and RANTES (8, 43, 50). Althoughhuman endothelial cells from some individuals were shown to killrickettsiae via a nitric oxide-dependent mechanism, the productionof nitric oxide by endothelium exposed to cytokines and RANTESwas not observed to occur for all donors. The precise cultureconditions or genetic factors responsible for these inconsistentresults have not been identified. Indeed, the most critical data,namely, whether or not human endothelial cells infected with rickettsiaesynthesize nitric oxide in vivo, remain to be determined. Furthermore,these studies extend the role of cytokine-activated H₂O₂-mediatedbactericidal activity to the control of the obligately intracellularbacterium R. conorii in its main target cells, human endotheliumand macrophages. Moreover, a role has been documented for IDO-mediatedlimitation of the availability of intracellular tryptophan asan antirickettsial mechanism in human macrophages. To the bestof our knowledge, this work represents the first demonstrationthat activated human endothelium and hepatocytes can kill intracellularrickettsiae, or indeed any microbial agent, via nitric oxide andthat human macrophages can kill intracellular rickettsiae viaIDO-mediated tryptophan starvation. It is the first demonstrationthat the chemokine RANTES plays a role in immunity to rickettsiaeand that it activates the microbicidal function of human endotheliumandhepatocytes.

Nitric oxide is associated with apoptosis of affected cells (2). Moreover, the interaction between the best-documentedpathogenic mechanism of cell injury by rickettsiae, namely, thestimulation of endothelial cell production of reactive oxygenspecies by rickettsial infection, and rickettsicidal mechanismsis worthy of consideration (7, 34, 38). The induction ofsuperoxide radical production might suggest a synergistic noxiouseffect via reaction with nitric oxide to produce the highly reactiveradical peroxynitrite. However, the balanced production of superoxideand nitric oxide results in less apoptosis than the equivalentunbalanced production of either of these radicals (1, 32,33). The scientific literature on the regulation of apoptosisfits some recent observations for rickettsia-infected endothelialcells, including activation of NF- $kappa$ B by intracellular rickettsiaeinvolving a signal transduction pathway leading to inhibitionof apoptosis (5). Although apoptotic loss of endothelium couldbe considered a pathologic event, it favors the host more thandoes the survival or necrosis of an infected endothelial cell.Survival of an infected endothelial cell would permit furthergrowth of the rickettsiae, and necrosis would release rickettsiae,allowing their spread to establish foci of infection in othercells. In contrast, rickettsia-containing apoptotic bodies wouldbe phagocytosed rapidly and digested intracellularly. However,the rates of survival of all of the cell types investigated underthe conditions of activation and infection in these experimentsindicated that death of the host cells, whether by apoptosis ornecrosis, was not the explanation for the control of rickettsialinfection. Intracellular R. conorii organisms were killed by nitricoxide-dependent, IDO-dependent, and H₂O₂-dependent antirickettsialmechanisms within viable hostcells.

It will be important in the future to design investigations of human subjects that will determine whether or not these mechanismsare active in vivo at the sites of infection and what the sourcesof cytokines and chemokines are. The most attractive hypothesiswould be that perivascular infiltrations of CD4 and CD8 T lymphocytes,macrophages, and natural killer cells, the infected endotheliumitself, and marginated cellular elements of blood secrete thecytokines and chemokines that activate infected endothelial cells,macrophages, and hepatocytes by paracrine and autocrine stimulationto kill intracellularrickettsiae.

	ACKNOWLEDGMENTS

We thank Josie Ramirez-Kim and Kelly Cassity for expert secretarial assistance in the preparation of the manuscript, ThomasBednarek and Gui-Min He for preparation of the figures, GustavoValbuena for establishment of the single-umbilical-cord HUVECculture, and Patricia Crocquet-Valdes for contributions to thetechnicaldesign.

This work was supported by a grant (AI21242) from the National Institute of Allergy and InfectiousDiseases.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Pathology and WHO Collaborating Center for Tropical Diseases, 301 UniversityBlvd., Galveston, TX 77555-0609. Phone: (409) 772-2856. Fax: (409)772-2500. E-mail: dwalker{at}utmb.edu.

Editor: W. A. Petri Jr.

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