Neutrophils Play a Protective Nonphagocytic Role in Systemic Mycobacterium tuberculosis Infection of Mice

doi:10.1128/IAI.68.2.577-583.2000

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Infection and Immunity, February 2000, p. 577-583, Vol. 68, No. 2
0019-9567/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Neutrophils Play a Protective Nonphagocytic Role in Systemic Mycobacterium tuberculosis Infection of Mice

Jorge Pedrosa,¹^,^* Bernadette M. Saunders,² Rui Appelberg,¹ Ian M. Orme,² Manuel T. Silva,¹ and Andrea M. Cooper²

Institute for Molecular and Cell Biology, University of Porto, Porto, Portugal,¹ and Mycobacteria Research Laboratories, Colorado State University, Fort Collins, Colorado²

Received 2 July 1999/Returned for modification 16 August 1999/Accepted 25 October 1999

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Evidence showing that neutrophils play a protective role in the host response to infection by different intracellular parasiteshas been published in the past few years. We assessed this issuewith regard to the infection of mice with Mycobacterium tuberculosis.We found a chronic recruitment of neutrophils to the infectionfoci, namely, to the peritoneal cavity after intraperitoneal infectionand to the spleen and liver after intravenous inoculation of themycobacteria. However, bacilli were never found associated withthe recruited neutrophils but rather were found inside macrophages.The intravenous administration of the antineutrophil monoclonalantibody RB6-8C5 during the first week of infection led to selectiveand severe neutropenia associated with an enhancement of bacillarygrowth in the target organs of the mice infected by the intravenousroute. The neutropenia-associated exacerbation of infection wasmost important in the liver, where a bacterial load 10-fold higherthan that in nonneutropenic mice was found; the exacerbation inthe liver occurred both during and after the neutropenic period.Early in infection by M. tuberculosis, neutropenic mice expressedlower levels of mRNAs for gamma interferon and inducible nitricoxide synthase in the liver compared to nondepleted mice. Theseresults point to a protective role of neutrophils in the hostdefense mechanisms against M. tuberculosis, which occurs earlyin the infection and is not associated with the phagocytic activityof neutrophils but may be of an immunomodulatorynature.

	INTRODUCTION

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The neutrophil is a professional phagocyte with a crucial role in the host defenses against infection by extracellular parasites.Recent data from mouse models show that the neutrophil also playsa protective role in infections by intracellular parasites. Resultsfrom several groups, including our own, demonstrate that the neutrophilis a key cell in the host defense against primary (4, 16,21, 40) and secondary (4, 22) infection by Listeria monocytogenes.Likewise, the neutrophil has been found to play a protective rolein infections by Candida albicans (30, 41, 42), Salmonellaenterica subsp. typhimurium (15), Francisella tularensis (49),Yersinia enterocolitica (15), Chlamydia trachomatis (6),and Toxoplasma gondii (45).

The importance of neutrophils in the host defense against intracellular microbes that cause chronic infections, such as mycobacteria,has previously been dismissed. There are two reasons for this.First, the neutrophil has a short life span, and second, the bacilligrow inside macrophages, thus being sheltered from the phagocyticactivity of the neutrophil. However, in support of a role forthese cells in chronic infections, we have shown that neutrophilsare persistently recruited to the sites of mycobacterial infection(5, 47). This neutrophil response is biphasic, with an earlyacute peak on the first day of infection followed by a secondinflux peaking around 8 to 15 days and lasting until the end ofthe infection. The first peak is nonspecific, while the secondis T cell dependent (1, 2). The importance of this neutrophilinflux has been addressed by studying the response to mycobacterialstrains of differing virulence or by comparing live and dead mycobacteria(47). Importantly, we have shown that the neutrophil responseis stronger and more persistent for both virulent and live mycobacteria(47). In addition, the in vitro antimycobacterial activity ofperitoneal macrophages was increased when macrophage cultureswere supplemented with neutrophil material (47).

Further support for a protective role of neutrophils in mycobacterial infections has been provided by the in vivo depletionof these cells by monoclonal antibody (MAb) RB6-8C5 treatment.In an intravenous (i.v.) model of Mycobacterium avium infection,mice depleted of neutrophils by using RB6-8C5 exhibited increasedsusceptibility to bacterial growth (3). This increased susceptibilitywas similar to that of mice which carry the beige mutation (3).Beige mice reconstituted with neutrophils from C57BL/6 mice exhibitedincreased resistance to M. avium infection (3). More recently,Petrofsky and Bermudez, using the same neutrophil depletion procedure,also showed that neutrophils play a protective role in the earlyresistance to M. avium infection (38). It is not yet clear whatrole neutrophils play in the lung, as RB6-8C5 depletion failedto exacerbate growth of bacteria in mice aerogenically infectedwith M. avium (43).

In the present work, we studied neutrophil recruitment during infection of mice with Mycobacterium tuberculosis and also theeffect of in vivo neutrophil depletion on bacterial proliferation.We show that neutrophils, which were found to be present at thefoci of M. tuberculosis infection, play an indirect, nonphagocyticrole in host protective mechanisms, probably via an effect oninnate production of gamma interferon (IFN- $gamma$ ).

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Mice. Female BALB/c mice were purchased from Jackson Laboratories (Bar Harbor, Maine) and infected when they were 6 to 8 weeks ofage.

Antibodies. The RB6-8C5 cell line was a kind gift from R. L. Coffman (DNAX Research Institute, Palo Alto, Calif.), and the GL-117 andJES5-2A5 cell lines, secreting $beta$ -galactosidase-specific and interleukin-10(IL-10)-specific MAbs, respectively, were a kind gift from DNAX.These hybridomas were grown in ascites fluid in HSD nude micepurchased from the Gulbenkian Institute (Oeiras, Portugal), andthe antibodies were purified by using a protein G-agarose column(Gibco, Paisley, UnitedKingdom).

Experimental infections. A virulent laboratory strain of M. tuberculosis (Erdman) was grown from a low-passage seed lot in Proskauer-Beck liquid mediumto mid-log phase, aliquoted, and frozen at $-$ 70°C.

To quantitatively assess neutrophil influx during the infection by M. tuberculosis, the peritoneal cavity model of infectionwas used (47). Mice were injected intraperitoneally (i.p.) with10⁵ CFU of M. tuberculosis or phosphate-buffered saline (PBS), andgroups of four or five mice were sacrificed at different timepoints.

Treated and untreated mice were i.v. infected, via the lateral tail vein, with 10⁵ CFU of strain Erdman. Mycobacterial proliferation was assessedat different time intervals by determining viable counts in liver,spleen, and lung until day 30 of infection. Serial dilutions ofwhole-organ homogenates were plated on Middlebrook 7H11 agar (LifeTechnologies, Gaithersburg, Md.), and bacterial colonies werecounted after incubation at 37°C for 20 days. The data are expressedas the log₁₀ of the mean number of bacteria recovered per organ(n = 4animals).

Study of neutrophil influx. The peritoneal leukocyte population in mice injected i.p. with mycobacteria or PBS (control) was analyzed. After peritoneallavage with 4 ml of PBS, total leukocyte numbers were determinedand differential cell counts were performed with cytospin preparations(Shandon cytocentrifuge) stained with the Diffquick stain (DateInternational, Miami, Fla.). Duplicate cytospin preparations werestained by the Ziehl-Neelsen method for the visualization of M.tuberculosisbacilli.

Neutrophil recruitment to foci of systemic infection was studied in liver and spleen at the time points indicated in Fig.2 and Table 1. Spleen cell suspensions were treated with a 0.15M ammonium chloride-0.010 M potassium bicarbonate solution tolyse erythrocytes. The cells were then washed, and total and differentialcell numbers were determined as described above for peritonealleukocytes. Liver tissue was fixed in 10% buffered formalin setin paraffin, sectioned, and stained with hematoxylin and eosin.Neutrophil influx was evaluated by counting the number of neutrophilsper microscopic field (with a 100× objective) in at least 50 fieldsper section. These numbers were transformed to correspond to cellnumbers per square millimeter. Duplicate preparations of bothspleen cell cytospin preparations and histological liver sectionswere stained by the Ziehl-Neelsen method for the visualizationof M. tuberculosisbacilli.

Neutrophil depletion. In order to assess the role of neutrophils in systemic infection by M. tuberculosis, i.v. infected mice were made neutropenicby treatment with MAb RB6-8C5, as previously described in detail(3, 4). Briefly, mice were injected i.v. in the lateraltail vein with 200 µg of MAb RB6-8C5 or with MAb GL-117 or PBSas controls (in an independent experiment it was found that theeffect of the administration of the isotype-matched control MAbGL-117 was not different from that of PBS). Two depletion periodswere used in the present study. Early depletion required antibodytreatment at 5 h, 2 days, and 4 days of infection. Late depletionrequired dosing on days 16, 18, and 20 of infection. Previousstudies with MAb RB6-8C5, showed severe neutrophil depletion inthe peripheral blood, spleen, and peritoneal cavity for 48 h followingthe i.v. injection of 0.2 mg of the antibody, with the numberof neutrophils returning to normal at day 3 after treatment (4).In this model, therefore, neutropenia is maintained until day6, with recovery at day 7 (3). The numbers of neutrophils inlivers and spleens of MAb RB6-8C5-treated mice were determinedas described above at the time points indicated in Fig. 2 andTable 1.

By laser-assisted confocal microscopy, we confirmed that MAb RB6-8C5 binds to neutrophils but not to mononuclear cells. Thisneutrophil-specific binding of RB6-8C5 was observed in both naiveand experimentally infected mice (J. Pedrosa et al., unpublisheddata).

In vivo treatments with rIL-12 or anti-IL-10. Mice were infected i.v. with M. tuberculosis Erdman and treated during the first week of infection with MAb RB6-8C5 or PBSas control. Neutralization of IL-10 was performed by i.p. injectionof a single dose of 2 mg of MAb JES5-2A5 at 5 h after infection(36). Recombinant IL-12 (rIL-12) (46) (a kind gift from S.Wolf and J. Sypek, Genetics Institute, Cambridge, Mass.) was reconstitutedin PBS and administrated i.p. in two doses of 0.4 µg at 5 h and2 days afterinfection.

Semiquantitative reverse transcriptase PCR reaction (RT-PCR). Liver segments were collected from infected mice, homogenized in Ultraspec (Biotecx Laboratories Inc., Houston, Tex.), rapidlyfrozen, and stored at $-$ 70°C. Total mRNA was extracted and reversetranscribed by using murine Moloney leukemia virus reverse transcriptase(Gibco BRL, Grand Island, N.Y.). Analysis of mRNA-specific cDNAsequences for IFN- $gamma$ and inducible nitric oxide synthase (iNOS)was performed by semiquantitative PCR (20). Briefly, cDNA wasdiluted and amplified by using Taq polymerase (Promega, Madison,Wis.) and specific primers (20, 53). The PCR product was blotted,probed with specific internal probes, and detected by using anenhanced chemiluminescence (ECL) kit (Amersham, Arlington Heights,Ill.). By using a limiting number of cycles for the PCR, a correlationbetween the amount of signal and the relative amounts of cDNAspecific for a particular product is obtained. The amount of readableRNA from each sample was compared by using primers specific forthe hypoxanthine phosphoribosyltransferase (HPRT) housekeepinggene. Samples that had similar HPRT signals were compared forthe expression of IFN- $gamma$ -specific and iNOS-specificsignals.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Persistent neutrophil recruitment is a feature of M. tuberculosis infection. As a first approach to quantitatively assess neutrophil influx during infection by M. tuberculosis, the recruitment of neutrophilsto the peritoneal cavity of mice infected i.p. was monitored overtime. We used this model since, as previously reported (5,47), peritoneal leukocyte populations can be easily and accuratelystudied both qualitatively andquantitatively.

Figure 1 demonstrates that the very low numbers of peritoneal neutrophils seen in noninfected mice increased in the i.p. inoculatedanimals, with peaks at 6 h and 11 days postinfection. An increasein the number of mononuclear cells in the peritoneal cavity wasfound after the third day of infection. No significant differencesbetween eosinophil and mast cell populations were seen (not shown).Control mice injected i.p. with PBS did not show a significantinflux of neutrophils (not shown).

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FIG. 1. Influx of neutrophils and mononuclear cells to peritoneal cavities of mice infected i.p. with 10⁵ CFU of M. tuberculosis. Peritoneal lavages were performed on groups of four or five mice at different time points, and total and differential leukocyte counts were done. Bars represent means and standard deviations. Statistical differences between noninfected and infected mice: *, P < 0.05; **, P < 0.01. Results are from one representative experiment of two independent experiments.

In order to assess the recruitment of neutrophils to M. tuberculosis infection foci during systemic infection, we studiedthe leukocyte populations in spleen and liver following infectionby the i.v. route. In the spleens of noninfected mice, high numbersof neutrophils were found (Fig. 2). These numbers increased significantlyafter day 3 in the i.v. inoculated animals (Fig. 2). The histologicalanalysis of liver sections showed that neutrophils were very rarein control mice but were recruited to this organ during the entirecourse of systemic infection by M. tuberculosis (Table 1).

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FIG. 2. Neutrophil and mononuclear cell populations of mouse spleens during systemic infection by M. tuberculosis. Mice were injected i.v. with 10⁵ CFU of M. tuberculosis and treated i.v. with the neutrophil-depleting MAb RB6-8C5 or with PBS (control). The antibody was administrated at 5 h, 2 days, and 4 days of infection. At the indicated time points, groups of four or five mice were sacrificed and spleen cell suspensions were obtained. After erythrocyte lysis, cells were washed and total and differential leukocyte counts were performed. Bars represent means and standard deviations. ND, not detectable. Statistical differences between noninfected and infected mice: *, P < 0.05; **, P < 0.01. Results are from one representative experiment of two independent experiments.

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TABLE 1. Numbers of neutrophils in liver sections of early neutrophil-depleted and nondepleted i.v. infected mice^a

At the infection foci, M. tuberculosis bacilli were never found associated with neutrophils but rather were found inmacrophages.

RB6-8C5 efficiently abrogates neutrophilia at infectious foci during systemic infection by M. tuberculosis. A severe, transient, and selective neutropenia was obtained by our protocol of administration of MAb RB6-8C5 in mice systemicallyinfected with M. tuberculosis. In fact, during a 6-day periodafter the beginning of the treatment with MAb RB6-8C5, no neutrophilswere found in the spleen by cytological analysis (Fig. 2). A similarneutropenia was found in the liver by histological analysis (Table1). No significant differences in the numbers of other leukocytesdue to the treatment with MAb RB6-8C5 were found in eitherorgan.

The depletion of neutrophils during the first week of infection exacerbates M. tuberculosis proliferation. Neutrophil depletion was carried out early in infection by the administration of three doses of the antibody at 5 h, 2 days,and 4 days after the inoculation of mycobacteria. The effect ofthis early neutrophil depletion on bacterial numbers was differentin each organ. In the lung, a significant exacerbation of mycobacterialproliferation was found at the end of the effective period ofdepletion, i.e., 7 days (Fig. 3). In the spleen, bacterial numberswere higher in MAb-treated animals than in control mice from day15 onwards. Finally, in the liver, the exacerbation of infectioninduced by the treatment with MAb RB6-8C5 occurred both duringthe neutropenic period and after recovery from the neutropenia.In this organ, at day 15 of infection the bacterial loads in neutropenicmice were 10-fold higher than those in the nondepleted animals.Differences in the mycobacterial numbers in the latter two organspersisted throughout the remaining course of the infection.

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FIG. 3. Effect of early neutrophil depletion on susceptibility of BALB/c mice to M. tuberculosis infection. Mice were injected i.v. with 10⁵ CFU of M. tuberculosis and treated with MAb RB6-8C5 (circles) or PBS as a control (squares) as described for Fig. 2. Groups of mice were sacrificed at different time points, and numbers of viable bacteria were determined by plating serial dilutions of organ homogenates on Middlebrook 7H11 medium. The results represent the geometric means and standard deviations of the CFU of four animals. Statistical differences between mice treated with MAb RB6-8C5 and mice treated with PBS: *, P < 0.05; **, P < 0.01. Results are from one representative experiment of three independent experiments.

In order to address the role of the antibody treatment in early bacterial growth, two independent experiments were performedwherein bacterial numbers in the liver, spleen, and lung weredetermined at day 3 of infection. Table 2 shows that no exacerbationof bacterial growth occurred at this early time point.

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TABLE 2. Effect of early neutrophil depletion of BALB/c mice on bacterial loads at day 3 of infection with M. tuberculosis^a

Early neutrophil depletion causes decreased expression of mRNAs for IFN- $gamma$ and iNOS in vivo. In order to assess the mechanism(s) through which neutrophils participate in the host defense against systemic infection byM. tuberculosis, we analyzed the expression of mRNAs for IFN- $gamma$ and iNOS in the livers of neutropenic and nondepleted mice infectedwith the bacilli, using RT-PCR.

We found that neutropenic mice expressed lower levels of mRNA for IFN- $gamma$ early in infection compared to nondepleted mice. Thisdecreased level of mRNA for IFN- $gamma$ was found during the neutropenicperiod, at day 3 of infection (Fig. 4). At this time point, nomessage for iNOS was found in either group of mice. Later in infection(day 7), we found a lower level of message for iNOS in the liversof mice that had been previously treated with the antineutrophilMAb RB6-8C5 than in the controls (Fig. 4).

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FIG. 4. Semiquantitative RT-PCR analysis of in vivo expression of IFN- $gamma$ , iNOS, and HPRT in mouse livers at 3 and 7 days after systemic infection with 10⁵ CFU of M. tuberculosis. Liver fragments were collected from control mice (mice injected with PBS) and from mice made neutropenic by treatment with MAb RB6-8C5 as described for Fig. 2. Each lane represents data from one animal after scanning of the Southern blots. Results are from one representative experiment of two independent experiments.

IL-10 neutralization or IL-12 administration partially abrogates the exacerbation of infection induced by early neutrophil depletion. The lower levels of mRNA expression for IFN- $gamma$ found in infected neutropenic mice compared to infected nondepleted mice couldbe the result of either a decreased production of IL-12 or anincrease in the levels of IL-10, or both. In order to test thishypothesis we assessed the effect of the neutralization of IL-10as well as the effect of the administration of IL-12 in neutropenicmice and in nondepletedmice.

While the administration of rIL-12 did not affect mycobacterial numbers in nondepleted mice, it clearly reduced the exacerbationof infection in the livers of mice treated with the antineutrophilantibody (Fig. 5). Treatment with anti-IL-10 MAb also resultedin reduced exacerbation of infection due to neutrophil depletion(Fig. 5).

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FIG. 5. Effects of IL-10 neutralization or IL-12 administration on host susceptibility to M. tuberculosis infection for normal and neutropenic mice. Mice were injected i.v. with 10⁵ CFU of M. tuberculosis and treated during the first week of infection with MAb RB6-8C5 (right panel) or PBS (left panel) as described for Fig. 2. Recombinant IL-12 was administrated i.p. at 5 h and 2 days after infection, and neutralization of IL-10 was done by i.p. injection, at 5 h after infection, of 2 mg of MAb JES5-2A5 ( $alpha$ IL-10); as a control for these treatments, mice were injected i.p. with PBS. Groups of mice were sacrificed at 14 days of infection, and numbers of viable bacteria were assessed. The results represent the geometric means and standard deviations of the CFU of four animals. Statistical differences between mice treated i.p. with PBS and mice treated i.p. with IL-12 or with MAb JES5-2A5: *, P < 0.05; **, P < 0.01. Results are from one representative experiment of two independent experiments.

Depletion of neutrophils during the third week of infection does not affect the proliferation of M. tuberculosis. If the increased susceptibility seen during MAb RB6-8C5 treatment is related to decreased innate responses, we would expectlate depletion to have very little effect on bacterial growth.We therefore depleted previously infected mice and compared theeffects of such treatment with a control infection. As shown inFig. 6, this depletion of neutrophils late in infection had noeffect on the mycobacterial loads in the three target organs studied.

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FIG. 6. Effect of late neutrophil depletion on the susceptibility of BALB/c mice to M. tuberculosis infection. The procedure and symbols are as for Fig. 3, except that MAb RB6-8C5 was injected at days 16, 18, and 20 after infection. Results are from one representative experiment of two independent experiments. Four mice were used per time point.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

As already reported for other mycobacteria (5, 47), we show here that infection with M. tuberculosis led to the persistentrecruitment of neutrophils to the sites of infection, namely,to the peritoneal cavity after i.p. infection and to the liverand spleen after i.v. infection. Importantly, the protective roleof this neutrophilic response was demonstrated by the increasedsusceptibility of neutropenic mice to M. tuberculosis.

Clearly, the depletion of neutrophils during the first week of infection allowed increased growth of M. tuberculosis in liver,spleen, and lung; this increase was most pronounced in the liver.At present we have no explanation for the importance of neutrophilsin protective responses in the liver. Interestingly, however,other related reports, on studies using a variety of infectiousagents, have also noted increased susceptibility in the liversof neutrophil-depleted mice (4, 6, 15, 21).

We do not feel that the protective function of the neutrophils is as a direct killer cell in the host resistance against M.tuberculosis. In support of this hypothesis, we did not find M.tuberculosis bacteria associated with neutrophils in either theperitoneal or splenic cytospin preparations or the histologicalsections of the liver; rather, the bacteria were clearly associatedwith or within macrophages. This observation indicates that thereis little opportunity for direct phagocytosis and intracellularkilling of M. tuberculosis by neutrophils in vivo. Other studieshave addressed the role of neutrophils in direct killing of M.tuberculosis. Brown (10) and Jones et al. (31) have demonstratedthat human neutrophils are capable of controlling the growth ofM. tuberculosis in cultures of human neutrophils, but their assaysdid not distinguish between intra- and extracellular killing.In contrast, Denis reported that human neutrophils were unableto kill M. tuberculosis even after activation with cytokines (24).

There are several plausible mechanisms that could mediate this indirect protective role of neutrophils against infection byintracellular parasites. These include immunomodulation throughproduction of cytokines and chemotactic factors (8, 9, 25,37-39, 41, 42, 50), secretion of granule components thatcan activate infected macrophages (26, 34, 35), and transferof neutrophilic antimicrobial materials to the macrophage (29,33, 34, 47).

Although we cannot exclude the other mechanisms mentioned above, we favor an immunomodulatory activity of the neutrophil,particularly in the liver. In fact, the increase in bacterialproliferation observed in the livers of the neutrophil-depletedmice occurred not only during the period of neutropenia but alsolater when neutrophils were again present in the host. The possibilityof an immunomodulatory role for neutrophils in the protectivemechanisms against M. tuberculosis is supported by the fact thatmouse neutrophils are known to secrete several cytokines, suchas IL-1 $alpha$ / $beta$ , IL-6, IL-10, IL-12, and tumor necrosis factor alpha(9, 11-13, 38, 41, 42).

Several of these cytokines are known to modulate the expression of IFN- $gamma$ , which is a key cytokine in the host defense mechanismsagainst M. tuberculosis in the mouse (18, 27). A second majorcomponent of the protective response is the macrophage productnitric oxide. This molecule is required to create a toxic environmentwithin the infected macrophage and is dependent on the enzymeiNOS for its production. In turn, the expression of iNOS is highlydependent upon IFN- $gamma$ expression (27). Interestingly, we observedthat the neutrophil-depleted mice expressed less mRNA for IFN- $gamma$ early during depletion (day 3) and that the loss of this IFN- $gamma$ resulted in reduced expression of iNOS mRNA later (day 7). Theseobservations clearly suggest that the presence of neutrophilsin the infection foci is important for the early production ofIFN- $gamma$ and that the decreased production of IFN- $gamma$ in neutropenicmice affects the nitric oxide-mediated antimycobacterial activityof infectedmacrophages.

The cellular source for the early IFN- $gamma$ is unlikely to be conventional T cells, since the effect occurs earlier than antigen-specificT cells emerge (17). There has been a recent spate of publicationsimplicating many types of cells of the innate immune system inthe production of IFN- $gamma$ . Natural killer (NK) cells produce IFN- $gamma$ in response to IL-12 and tumor necrosis factor alpha (28). Inaddition, NK cells which express an $alpha$ $beta$ T-cell receptor (NK T cells)have been shown to release several cytokines and chemokines veryrapidly upon activation and have been suggested to play a rolein initiating and/or modulating the acquired immune response (7).At this time we have no data supporting the role of any particularcell type in the neutrophil-dependent early expression of IFN- $gamma$ .We suggest, however, that the presence of neutrophils is requiredfor IFN- $gamma$ production by cells of the innate immune system earlyafter infection. Consistent with this interpretation, no effecton bacterial proliferation was seen as a consequence of a laterneutrophil depletion induced during the third week of infection,when protective T cells have already beeninduced.

IL-10 and IL-12 are cytokines that are induced by bacterial infection and which also modulate IFN- $gamma$ expression (51, 52).IL-12 acts directly on cells to both induce and expand their abilityto make IFN- $gamma$ . In contrast, IL-10 acts on IL-12-producing cellsto inhibit production of this cytokine and therefore indirectlylimit IFN- $gamma$ production (23, 32). The protective role of IL-12in infections by intracellular parasites, including M. tuberculosisand M. avium, have been well described (14, 19, 20, 44,48). Moreover, in experimental models of murine candidiasisand toxoplasmosis, one source of protective IL-12 was the neutrophilpopulation (9, 42). In addition, it was recently reportedthat neutrophils isolated from mice early after infection withM. avium produce increased amounts of IL-12 compared to neutrophilsfrom uninfected mice (38). We therefore hypothesize that innormal mice exposed to M. tuberculosis, neutrophils produce excessIL-12 which limits the effect of any IL-10 expressed. This excessIL-12 then tips the balance in favor of early IFN- $gamma$ production.In the neutrophil-depleted mice there is insufficient IL-12, andtherefore IL-10 dominates, resulting in reduced early IFN- $gamma$ . Insupport of this hypothesis, we report here that both the additionof rIL-12 and the inhibition of IL-10 resulted in a reduced exacerbatoryeffect of the antineutrophiltreatment.

In summary, our results show that neutrophils play a protective role in a murine model of systemic infection by M. tuberculosis.In particular, these cells are important in limiting bacterialgrowth in the liver. The protective nature of the neutrophil wasin evidence during the early period of the infection and was mediatedvia a nonphagocytic, possibly immunomodulatory, mechanism whichaffected IFN- $gamma$ production.

	ACKNOWLEDGMENTS

This work was supported by grants from NIH (contract AI40488) and JNICT (Lisbon, Portugal) (contract PECS/P/SAU/60/95).

We thank R. L. Coffman and the DNAX Research Institute for providing hybridoma cell lines and S. Wolf and J. Sypek (GeneticsInstitute) for providing rIL-12.

	FOOTNOTES

^* Corresponding author. Mailing address: Institute for Molecular and Cell Biology, University of Porto, Rua do Campo Alegre,823, 4150 Porto, Portugal. Phone: 351-226074900. Fax: 351-226099157.E-mail: jpedrosa{at}ibmc.up.pt.

Editor: S. H. E. Kaufmann

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