Role of hypothermia induced by tumor necrosis factor on apoptosis and function of inflammatory neutrophils in mice

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Role of hypothermia induced by tumor necrosis factor on apoptosis and function of inflammatory neutrophils in mice

Toshiko Mizuno¹, Yukiko Kannan¹, Midori Tokunaga¹, Mitsuaki Moriyama¹, Yasuo Kiso²^,⁵, Ken Kusakabe², Jyoji Yamate³, Kenichi Kiyomiya⁴, and Tsukasa Sugano¹

¹ Department of Veterinary Physiology, ² Department of Veterinary Anatomy, ³ Department of Veterinary Pathology, and ⁴ Department of Toxicology, College of Agriculture, Osaka Prefecture University, Sakai 599-8531; and ⁵ Department of Veterinary Anatomy, Faculty of Agriculture, Yamaguchi University, Yamaguchi 753-8515, Japan

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Changes in body temperature and cell infiltration, mediated by cytokines including tumor necrosis factor- $alpha$ (TNF- $alpha$ ), occurduring inflammation, but a role of body temperature on inflammatoryresponses remains obscure. Intraperitoneal injection of 10% caseinto mice resulted in transient hypothermia followed by neutrophilaccumulation in peritoneal cavities. Peritoneal TNF- $alpha$ was rapidlyraised, and pretreatment of mice with an anti-TNF- $alpha$ antibody promotedtemperature restoration and partially inhibited neutrophil accumulation.To investigate direct effects of body temperature on neutrophils,peritoneal or peripheral blood neutrophils were cultured at 35°Cor 37°C with or without recombinant murine TNF- $alpha$ (100 ng/ml) ora protein synthesis inhibitor cycloheximide (1 µg/ml). Significantinhibition of spontaneous and TNF- $alpha$ -induced apoptosis was obtainedat 35°C compared with 37°C, an effect that was not altered bythe addition of cycloheximide. Moreover, phagocytic ability ofperitoneal neutrophils was significantly enhanced by incubatingthem at the lower temperature. These results indicate that mildhypothermia induced by endogenous TNF- $alpha$ has enhancing roles onneutrophil survival and function during peritonealinflammation.

inflammation; body temperature; tumor necrosis factor- $alpha$

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

INFLAMMATION IS A COMPLEX cellular and biochemical response to injurious stimuli and is regulated by an extensive networkof cytokines. Above all, tumor necrosis factor- $alpha$ (TNF- $alpha$ ) is wellknown to be released immediately after an injury to local tissueand to play multiple roles in acute phase responses includingrecruitment of neutrophils and fever. Neutrophils primarily accumulateand play a pivotal role in host defense by phagocytosing and killingmicrobes or scavenging irritants but are relatively short-livedand die by apoptosis. TNF- $alpha$ is known to stimulate neutrophil adhesionto endothelial cells (11, 19) and to enhance phagocytosisand superoxide production of neutrophils (1, 28). TNF- $alpha$ ,on the other hand, has been reported to promote neutrophil apoptosis(31, 39, 41, 42, 46).

Fever is currently thought to be caused by endogenous pyrogens released by macrophages and accessory cells during injury andinflammation, and TNF- $alpha$ as well as interleukin (IL)-1 and -6 areregarded as pyrogens (22). Actually, there are several reportsin which the injection of TNF- $alpha$ produced fever in human and experimentalanimals (30, 37). In addition, polyclonal and monoclonal antibodiesagainst TNF- $alpha$ (anti-TNF) have been found to attenuate lipopolysaccharide(LPS)- and turpentine-induced fever (4, 18, 29). However,Long et al. (26) have shown opposite results, that is, anti-TNFfurther enhanced LPS-induced fever, and Klir et al. (21) havereported that intraperitoneal injection of human recombinant TNF- $alpha$ attenuated LPS-induced fever in rats. Moreover, hypothermia wasobserved immediately following injection of relatively high concentrationsof LPS in mice and rats, and anti-TNF and TNF- $alpha$ -soluble receptorprevented this (6, 23). Furthermore, Leon et al. (24) justrecently reported that TNF p55/p75-receptor (TNFR) knockout miceattenuated hypothermia induced by cecal ligation and puncture(CLP). These results suggest a possible role for TNF- $alpha$ not onlyas a pyrogen but also as an antipyretic factor (cryogen) to limitthe magnitude of fever or more actively lower bodytemperature.

As to a physiological role of body temperature on neutrophil function, it has been generally reported that mild hyperthermia(up to 40°C) activates neutrophil function, but severe hyperthermia(more than 42°C) or hypothermia inhibits it (15, 44, 45,47, 48). However, most of the results were obtained from invivo experiments in which body temperature was changed physicallyor chemically or in vitro experiments using peripheral blood neutrophils,some of whose physiological characteristics are known to be differentfrom those of inflammatory or tissue neutrophils (2, 31,49). Thus the present study was performed to determine whethera physiological correlation between neutrophil accumulation andchanges in body temperature exists and the role of endogenousTNF- $alpha$ in this correlation during acute inflammation by using miceinjected intraperitoneally with casein. Moreover, to investigatea possible role of changes in body temperature on neutrophil functionat an inflammatory site, we studied the effect of different incubationtemperatures within a physiological range on apoptosis of neutrophilsisolated from the casein-injected peritoneal cavity and from normalperipheral blood and on phagocytic activity of peritoneal neutrophils.Most of all, this is the first report demonstrating that physiologicaltemperature changes directly alter the progress of neutrophilapoptosis.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Mice. Albino ICR mice (from Japan SLC, Hamamatsu, Japan) were raised in our laboratory, and male mice aged 2-3 mo were usedin thisstudy.

Measurement of body temperature. Rectal temperature was measured using an electric thermometer with a probe (Muromachi Kikai,Tokyo, Japan) every 1 h after mice were injected intraperitoneallywith 2 ml of various doses of LPS-free sodium caseinate (casein;Wako Pure Chemical Industries, Osaka, Japan) in saline warmedto 37°C. A mouse was put on a metal cover of a cage, and the tailwas gently held, then the probe was inserted 1.7 cm into the rectum.Experiments were conducted after mice were trained for severaldays. In some experiments, mice were preinjected with 1 ml polyclonalrabbit anti-mouse TNF- $alpha$ (Genzyme, Cambridge, MA) diluted 50-foldin saline and warmed to 37°C 2 h before the injection ofcasein.

Isolation of peritoneal exudate cells. Isolation of peritoneal exudate cells (PEC) after casein injection was carried outby techniques previously described (16, 17). Briefly, micewere killed by decapitation 5 h after intraperitoneal injectionof 10% casein, and PECs were collected by washing the peritoneumwith MEM (Gibco BRL Life Technologies, Rockville, MD) containing1% heparin. PECs, in which the population of neutrophils was greaterthan 80%, estimated by Giemsa staining, were used for thecultures.

Isolation of peripheral blood neutrophils. Heparinized peripheral blood was obtained from intact mice by cardiac punctureunder pentobarbital sodium anesthesia (0.1 mg/100 g body wt).Neutrophils were purified by a method described by Tsuchida etal. (42). Briefly, the heparinized blood was mixed with an equalvolume of 37°C plasma gel that had been prepared as follows. Threegrams of gelatin, 0.7 g of NaCl, and 0.2 g of CaCl₂ were dissolvedin 100 ml distilled water at 60°C and stored at 4°C. The mixtureof blood and plasma gel was allowed to stand until erythrocyteswere settled. The leukocyte-rich supernatant was transferred toan another tube and washed with MEM. The pellet was suspendedin 5 ml MEM and overlayered onto the same volume of Ficoll-Paque(sp. gr. 1.077; Amersham Pharmacia Biotech, Uppsala, Sweden),then centrifuged at 800 g for 10 min at 4°C. The pellet containingneutrophils and erythrocytes was allowed to lyse the erythrocyteswith hypotonic NaCl and was washed with MEM twice. The purityof neutrophils was more than 75% (the remaining cells were mostlylymphocytes).

Cell culture. PECs were cultured in 24-well tissue culture plates (Becton Dickinson, Tokyo, Japan). Each well contained 10⁶ PECs in 1 ml $alpha$ MEM (GIBCO) supplemented with 1% newborn calf serum(NCS; GIBCO) with or without 100 ng/ml recombinant mouse TNF- $alpha$ (rmTNF- $alpha$ ; Pepro Tech, Rocky Hill, NJ) or 1 µg/ml cycloheximide(CHX; Wako). Peripheral blood neutrophils were cultured at 10⁵ cells/100 µl in each well of 96-well plates (Becton Dickinson).Plates were incubated at 35°C or 37°C in a fully humidified atmosphereof 5% CO₂ inair.

Examination of apoptosis. Morphological examination of apoptosis was performed by using Giemsa staining. Briefly, cells werespun in a cytocentrifuge (Cytospin; Shandon Scientific, Cheshire,Wales, UK) and were fixed in methanol followed by staining for30 min with 10-times diluted Giemsa solution. Giemsa-stained preparationswere observed under light microscopy (×400), and percentages ofapoptotic neutrophils were estimated from 200 Giemsa-stained neutrophilsper slide (16). Neutrophil apoptosis was also confirmed by stainingwith 1 µg/ml DNA-specific fluorochrome Hoechst 33258 under fluorescentmicroscopy.

Electrophoresis of DNA. Isolation and electrophoresis of PEC DNA were carried out by a modification of a technique describedby Ishizawa et al. (14). Briefly, 5 × 10⁵ PECs, cultured with or without rmTNF- $alpha$ at 35°C or 37°C, weresuspended in 200 µl PBS in a 1.5-ml microfuge tube. Ten microlitersproteinase K (10 mg/ml; Sigma Chemical, St. Louis, MO), 10 µlRNase (10 mg/ml ribonuclease A; Sigma), and 50 µl 5% SDS wereadded and incubated at 37°C for 30 min. After addition of 300µl NaI solution and incubation at 60°C for 15 min, 500 µl 100%isopropanol (Wako) were added, then vigorously shaken, and allowedto stand for 15 min at room temperature. The NaI solution contained6 M sodium iodide (Wako), 13 mM EDTA (EDTA-Na, Wako), 0.5% sodium-N-lauroylsarcosinate(Wako), 10 mg/ml glycogen (Wako), and 26 mM Tris-HCl (pH 8, Wako).A tube was centrifuged at 15,000 g for 15 min to precipitate DNA,the supernatant was discarded, 1 ml 50% isopropanol was added,and the mixture was centrifuged at 15,000 g for 15 min. Afterthe supernatant was discarded, 1 ml 100% isopropanol was addedand centrifuged at 15,000 g for 15 min. The DNA precipitate wasvacuum-dried and dissolved in 50 µl Tris-EDTA (TE) buffer at 4°C.TE buffer contained 100 µl 40 mM Tris-HCl, 10 µl 1 mM EDTA, and890 µl ultrapurified water. Twenty five microliters of each samplewere mixed with 2 µl loading buffer (0.25% bromophenol blue and40% sucrose) and loaded into each well of a 2% agarose gel containing1 µg/ml ethidium bromide. As a molecular size standard of DNA,1 µl marker solution (Maker 4, $phi$ ×174/Hae digest; Wako) was mixedwith 24 µl TE buffer. Electrophoresis was carried out at 100 V,80 mA, until the marker dye had migrated 3-4cm.

TNF- $alpha$ bioassay. TNF- $alpha$ in a peritoneal exudate fluid (PEF) was measured using a modification of a bioassay technique previouslydescribed (9). PEFs were frozen at $-$ 80°C until used. Assayswere performed using TNF- $alpha$ -sensitive L929 tumorigenic murine fibroblastcell line. L929 cells were seeded at 10⁴ cells/well in 100 µl DMEM (GIBCO) containing 10% NCS in a 96-wellflat-bottom microtiter plate (Becton Dickinson) and incubatedfor 12 h in 5% CO₂ atmosphere at 37°C. The medium was discardedand replaced with 100 µl PEF solution diluted 40- to 80-fold byMEM containing 5% NCS. To construct a dose-response curve, 100µl of the serial dilutions of rmTNF- $alpha$ were added. One hundredmicroliters actinomycin D (final concentration 1 mg/ml; Wako)were also added, and a plate was incubated for 18 h. Supernatantwas removed, and cells were treated with 40 µl 2% crystal violet(in 25 mM methanol) for 20 min. After 100 µl 0.5% SDS were added,absorbance was measured at 570 nm on Immuno Reader NJ-2001 (NipponInterMed, Tokyo, Japan). TNF- $alpha$ values for PEF samples were determinedfrom a standard curve generated using rmTNF- $alpha$ .

Phagocytosis assay. Phagocytosis was assessed using a modified technique previously described (17). PECs were suspendedat a concentration of 2 × 10⁵ cells/ml in $alpha$ MEM containing 1% NCS. Hydrophilic microsphere lumispheres(2-µm diameter; Toray Research Center, Tokyo, Japan) were suspendedat 2 × 10⁸ microspheres/ml in PBS. Ten microliters rmTNF- $alpha$ (100 ng/ml) orMEM were mixed with 90 µl cell suspension and 10 µl lumispheresolution. The mixture was incubated for 20 min at 35°C or 37°C.To stop the phagocytic response, 1 ml cold PBS was added. Aftercentrifugation at 1,500 rpm for 5 min, 10 µl fuchsin solutiondiluted 10-fold were added to the pellet. Extracellular lumisphereswere stained red with fuchsin, but they were transparent whenphagocytosed. Under light microscopy (×400), the percentages ofneutrophils phagocytosing more than one lumisphere were estimatedfrom a total of 200neutrophils.

Statistical analysis. ANOVA followed by Fisher's post hoc test (protected least-squares difference) was performed for multiplecomparison.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Cell influx and body temperature changes induced by intraperitoneal injection of casein. Figure 1A shows the time course ofthe values of total PECs and peritoneal neutrophils after injectionof a 10% casein solution. To eliminate the influence of circadianrhythms on leukocyte function (13, 40), PECs were collectedbetween 1200 and 1500. PEC values increased rapidly, and a maximumresponse was observed 15 h after injection. At 5 h after the injection,PECs contained mostly neutrophils (81.8 ± 0.3%) but containedsome of both neutrophils (63.5 ± 3.5%) and monocytes (33.8 ± 2.3%)at 15 h.

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Fig. 1. Peritoneal exudate cell (PEC) and neutrophil numbers (A) and body temperatures (B) after intraperitoneal injection of 10% casein into mice. Collection of PECs and measurement of rectal temperature were performed just before injection (0 h) and 1, 2, 5, 10, 15, 24, and 48 h after the injection. Each value is a mean ± SE (n = 2-7). * P < 0.05, ** P < 0.01 compared with 0 h, and # P < 0.01 compared with saline by ANOVA/Fisher's protected least-squares difference (PLSD).

Body temperature fell suddenly after injection of 10% casein (Fig. 1B). Just before the casein injection, the average rectaltemperature of mice was 38.0 ± 0.1°C and fell to 34.8 ± 0.6°C1 h after the injection. On the other hand, saline injection didnot cause rectal temperature to fall after 1 h (37.5 ± 0.4°C and38.2 ± 0.5°C, before and 1 h after the injection, respectively).Until 3 h, temperature was still significantly lower in the casein-injectedmice compared with saline-injected mice or with 0 h, but it recoveredafterwards.

We examined the effects of 2% and 5% casein in addition to 10% casein, but no significant differences of body temperaturefrom saline injection were observed nor was there neutrophil accumulationuntil 5 h after the smaller doses of casein injection (data notshown).

From these results, we deduced that intraperitoneal injection of 10% casein caused a rapid decrease in mouse body temperatureand neutrophil accumulation during the restoration of bodytemperature.

TNF- $alpha$ levels in PEFs after casein injection. PEFs were drawn 1 and 5 h after injection of saline or 2, 5, and 10% casein,and TNF- $alpha$ bioactivity was assessed (Table 1). A dramatic elevationof TNF- $alpha$ concentration was observed 1 h after 10% casein injection(632.83 ± 257.90 ng/ml). At 5 h, the TNF- $alpha$ concentration had decreasedbut was still relatively high (92.53 ± 34.69 ng/ml). Casein at2% and 5% did not cause significant release of TNF- $alpha$ at 1 and5 h after injection.

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Table 1. TNF- $alpha$ activity in PEF after injection of various doses of casein

To investigate the roles of internally elevated TNF- $alpha$ on the changes in body temperature and neutrophil infiltration, anti-TNFwas applied 2 h before injection of 10% casein (Fig. 2A). Completeblockade of the TNF- $alpha$ activity in the PEF sample withdrawn 1 hafter 10% casein injection was confirmed by anti-TNF treatmentusing the above-mentioned bioassay (data not shown). Anti-TNFitself had no effect on body temperature before injection of casein.Also, body temperature decreased 1 h after the injection of caseinin the presence of anti-TNF to the same extent as in the presenceof saline ( $-$ 2.82 ± 0.50°C vs. $-$ 2.85 ± 0.76°C from 0 h). However,anti-TNF promoted restoration of body temperature, that is, significantlyelevated body temperature 2 h after casein injection, whereasit takes 4 h to significantly recover temperature without anti-TNFpretreatment.

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Fig. 2. Effects of pretreatment of anti-tumor necrosis factor (TNF) antibody on changes in body temperature (A) and peritoneal neutrophil numbers (B) after injection of 10% casein. Anti-TNF diluted 50-fold in saline or only saline was intraperitoneally injected 2 h before injection of 10% casein or saline. Changes in body temperature indicate difference of temperatures based on 0 h. Each value is a mean ± SE (n = 4-15). * P < 0.01 compared with 1 h and # P < 0.01 compared with saline + casein by ANOVA/Fisher's PLSD. PECs were collected 5 h after injection of casein (or saline as a control), and number of neutrophils was counted. * P < 0.05 and ** P < 0.01 compared with saline + casein by ANOVA/Fisher's PLSD.

Anti-TNF pretreatment also partially inhibited neutrophil infiltration caused by injection of 10% casein (Fig. 2B). The numberof peritoneal neutrophils was 9.24 (±1.76) × 10⁶ cells in anti-TNF pretreatment and 19.81 (±3.09) × 10⁶ cells in saline pretreatment 5 h after casein injection. In thecase of anti-TNF pretreatment followed by saline injection, thenumber of peritoneal neutrophils was 2.03 (±0.29) × 10⁶cells.

It was therefore found that TNF- $alpha$ , which was rapidly released into the peritoneal cavity by casein injection, not only enhancedneutrophil infiltration but also delayed recovery of decreasedbodytemperature.

Effect of incubating temperature on apoptosis of neutrophils in vitro. We next examined the direct effect of changes in temperaturewithin a physiological range on apoptosis of neutrophils. PECscollected 5 h after injection of 10% casein were incubated at37°C or 35°C for up to 24 h in medium with or without the additionof 100 ng/ml rmTNF- $alpha$ and stained with Giemsa. Apoptosis was determinedby typical morphological features such as condensed nuclei, vacuolatedcytoplasm, and some apoptotic bodies as described previously (16).Morphological features of apoptotic nuclei were also confirmedby Hoechst 33258 staining (data not shown). As shown in Fig. 3A,the population of apoptotic neutrophils was increased more rapidlyat 37°C (on and after 6 h) than at 35°C (on and after 18 h) inboth the presence and the absence of TNF- $alpha$ . TNF- $alpha$ acceleratedongoing apoptosis at 37°C after 18 h, but not at 35°C until 24h. We also cultured PECs at 39°C, and a significant increase ofapoptotic neutrophils was obtained during 3-12 h in culture comparedwith 37°C (data not shown).

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Fig. 3. Effect of incubation temperature on apoptosis of peritoneal neutrophils (A) and peripheral blood neutrophils (B) in vitro. A: PECs were collected 5 h after injection of 10% casein and were cultured for 6, 12, 18, or 24 h in presence (closed symbols) or absence (open symbols) of 100 ng/ml recombinant mouse (rm) TNF- $alpha$ at 37°C or 35°C. Proportion of apoptotic neutrophils was assessed by morphological observation of Giemsa-stained preparations under light microscopy. Each value is a mean ± SE (n = 13-21). * P < 0.01 compared with 0 h, # P < 0.01 compared with 37°C control and 35°C TNF- $alpha$ at 18 h, and § P < 0.01 compared with 35°C control by ANOVA/Fisher's PLSD. B: blood neutrophils were cultured for 18 h. * P < 0.05 and ** P < 0.01 by ANOVA/Fisher's PLSD.

For biochemical estimation of apoptosis, DNA was isolated from PECs cultured for 3 and 10 h at 37°C or 35°C and electrophoresedby agarose gel. As shown in Fig. 4, the ladder with ~200-bp typicalsteps of endonuclease activation did not appear in DNA of PECcultured for 3 h at both 37°C and 35°C (lanes 1-4), regardlessof the presence or the absence of rmTNF- $alpha$ . However, typical ladderswere observed in DNA of PEC cultured for 10 h at 37°C in whichthe density of the ladder was greater in DNA of PEC cultured withTNF- $alpha$ (lane 6) than without TNF- $alpha$ (lane 5). On the other hand,at 35°C, distinct ladders were barely visible both in culturewith or without TNF- $alpha$ (lanes 7 and 8).

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Fig. 4. Agarose gel electrophoresis of DNA isolated from 5 × 10⁵ PECs cultured at 35°C and 37°C. Lanes 1-4, DNA cultured for 3 h; lanes 5-8, DNA cultured for 10 h. Lanes 1 and 5, DNA cultured at 37°C in control medium; lanes 2 and 6, DNA cultured at 37°C in medium containing 100 ng/ml rmTNF- $alpha$ ; lanes 3 and 7, DNA cultured at 35°C in control medium; lanes 4 and 8, DNA cultured at 35°C in medium containing rmTNF- $alpha$ . Lane M, a molecular size standard ( $phi$ ×174/Hae digest, Maker 4). Molecular sizes in bp are indicated on left for gel. Similar results were obtained from 3 experiments.

These results indicate that apoptosis of peritoneal neutrophils was delayed as temperature of culture was lowered in a physiologicalrange and that the lower temperature also disturbed TNF- $alpha$ -promotedneutrophilapoptosis.

To further examine whether lower temperature inhibition of apoptosis is restricted to inflammatory neutrophils or not, wenext assessed apoptosis of neutrophils isolated from peripheralblood of intact mice. Equal to the peritoneal neutophils, incubationfor 18 h at 35°C decreased both spontaneous and TNF-induced apoptosisof blood neutrophils compared with 37°C (Fig. 3B), thus suggestingthat lower temperature suppresses neutrophil apoptosis in a neutrophilactivation- or localization-independentmanner.

Role of protein synthesis in temperature-dependent inhibition of neutrophil apoptosis. To understand the mechanism by whicha lower temperature suppresses neutrophil apoptosis, 1 µg/ml CHX,a protein synthesis inhibitor, was added to the PEC culture medium,which was then cultured for 18 h at 37°C or 35°C (Fig. 5). Significantpromotion of neutrophil apoptosis was observed by the additionof CHX at 37°C (36.40 ± 3.46% vs. 23.85 ± 2.73% with or withoutCHX), but not at 35°C. This suggests that the neutrophils synthesizedapoptosis inhibitory protein during culture at 37°C, but the loweredtemperature (35°C) suppressed apoptosis in a protein synthesis-independentmanner.

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Fig. 5. Effect of protein synthesis inhibitor on temperature-dependent apoptosis of peritoneal neutrophils. PECs were cultured for 18 h with 1 µg/ml cycloheximide (CHX) at 37°C or 35°C. Proportion of apoptotic neutrophils was assessed by morphological observation of Giemsa-stained preparations. Each value is a mean ± SE (n = 10). * P < 0.01 compared with 37°C control and 35°C CHX by ANOVA/Fisher's PLSD.

Effect of incubating temperature on phagocytosis of peritoneal neutrophils. Finally, to examine whether changes in temperatureregulate not only neutrophil apoptosis but also its phagocyticfunction, PECs (2 × 10⁵/ml) were incubated with lumispheres (2 × 10⁶/ml) in the presence or absence of 100 ng/ml rmTNF- $alpha$ at 37°C or35°C for 20 min. As shown in Table 2, in the absence of TNF- $alpha$ ,the percentage of lumisphere-phagocytosing cells was significantlyhigher at 35°C than at 37°C. We also counted the number of lumispheresper neutrophil, and the percentage of neutrophils phagocytosingmore than four particles was significantly higher at 35°C thanat 37°C (data not shown). Addition of TNF- $alpha$ , although not significantly,tended to increase the phagocytosis by the same extents (~1.1times controls) at 37°C and 35°C. Accordingly, the lower temperaturewas found to be beneficial in the promotion of phagocytosis ofperitoneal neutrophils.

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Table 2. Effect of incubation temperature and rmTNF- $alpha$ on peritoneal neutrophil phagocytosis (%)

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In the present study, we demonstrated that intraperitoneal injection of 10% casein into mice induced a rapid decrease of rectaltemperature, which reached a maximum at 1 h after injection, followedby gradual restoration by 15 h postinjection (Fig. 1B). Duringtemperature restoration, neutrophil infiltration into the peritonealcavity occurred and the population of neutrophils in total PECsreached a maximum after 5 h (Fig. 1A). Kitamura et al. (20)demonstrated the occurrence of a short-lasting fever after injecting0.2% casein into rabbits that caused the rectal temperature toincrease for 90 min after injection then peak at ~5 h (+0.8 ±1.0 °C compared with a baseline) and finally decreased to thecontrol level by 12-24 h. Neutrophil accumulation, in their experiments,was reported to reach a peak after 5 h, coinciding with our results.There are many reports indicating that LPS administration inducedmono- or biphasic fever in various animals (22, 33). However,it has been recently reported that larger doses of LPS inducedhypothermia and shock, whereas smaller doses caused fever in ratsand mice (34). Therefore, we examined the effects of 2% and5% casein in addition to 10% casein, but hyperthermia was notdetected by the two smaller doses of casein (data not shown).In LPS-induced hypothermia, TNF- $alpha$ has been considered to functionas a cryogen, although it was originally thought to be a memberof the endogenous pyrogens, because pretreatment of animals withneutralizing anti-TNF antibody before LPS injection resulted inenhancement of fever (26) or suppression of hypothermia (6).Moreover, intraperitoneal injection of TNF- $alpha$ has been reportedto show an antipyretic effect on febrile response to LPS (21).Attenuation of hypothermia was also observed in TNFR knockoutmice in response to CLP, another model of sepsis (24). In ourstudy, 10% casein induced a dramatic rise in intraperitoneal TNF- $alpha$ level during the first hour, and a considerable amount of TNF- $alpha$ was retained 5 h after the injection (Table 1). Although anti-TNFpretreatment 2 h before 10% casein injection did not block thecasein-induced initial decline of body temperature, it significantlypromoted the restoration of temperature to control values (Fig.2A), indicating that endogenous TNF- $alpha$ released by casein injectionlimited the increase in temperature during convalescence. It hasbeen demonstrated that LPS-induced hypothermia occurred as a resultof reduced thermogenesis (7), and Holt et al. (12) have reportedthat intracerebral injection of recombinant TNF- $alpha$ decreased theactivity of sympathetic efferent nerves to intercapular brownadipose tissue, a main effector of nonshivering thermogenesis.It should be clarified whether TNF-retained hypothermia in ourinflammatory model occurred by the similar mechanism in a futurestudy. The primary inducer of the hypothermia after casein injectionis still uncertain, but other endogenous cryogens such as $alpha$ -melanocyte-stimulatinghormone, arginine-vasopressin, glucocorticoid, leukotrienes, orprostaglandin D₂ might be involved in it (5, 6, 25, 27,43).

Preinjection of anti-TNF partially decreased the 10% casein-induced neutrophil accumulation (Fig. 2B), implying that TNF- $alpha$ is involved in the stimulation of neutrophils in the interstitialspace during inflammation. Such involvement of TNF- $alpha$ in neutrophilinfiltration was also reported by others using immune complex-inducedinflammation of the murine peritoneum (50). This effect of TNF- $alpha$ is considered to be due to the stimulation of neutrophil-endothelialinteraction, which is a pivotal event in neutrophil emigrationfrom the intravascular to inflammatory sites (11, 19).

Neutrophils exudated to local tissue are destined to undergo apoptosis followed by recognition and phagocytosis by tissuemacrophages (35). Therefore, suppression of apoptosis contributesto maintenance of neutrophil function, and many proinflammatorycytokines not only enhance neutrophil function but also suppressthe apoptosis (3, 10, 28, 39). TNF- $alpha$ , however, has beenreported to promote neutrophil apoptosis (31, 39, 41, 42,46) while enhancing the function (1, 28). Because changesin body temperature are considered to alter immune/inflammatoryresponses (22), we questioned whether they affect neutrophilapoptosis. When PECs isolated from peritoneal cavities 5 h after10% casein injection were incubated at 35, 37, or 39°C, significantdecrease of neutrophil apoptosis was observed at 35°C comparedwith 37°C (Fig. 3A) and at 37°C compared with 39°C (data not shown).Addition of 100 ng/ml rmTNF- $alpha$ , which was the approximate concentrationin PEFs (5 h after the casein injection), showed accelerationof neutrophil apoptosis when cultured at 37°C, but not at 35°C(Fig. 3A). Because the peritoneal neutrophils had already beenexposed by various inflammatory mediators, some of which promoteapoptosis, whereas others antagonize apoptosis, as stated above,we next did the same in vitro experiment by using nonactivatedneutrophils isolated from peripheral blood of intact mice (Fig.3B). Similar to the results of the peritoneal neutrophils, spontaneousand TNF- $alpha$ -induced apoptosis of blood neutrophils were suppressedby the lower temperature, suggesting that apoptotic response ofneutrophils to temperature is in an inflammatory activation- orneutrophil localization-independent manner. As we know, this isthe first report that temperature (within a physiological range)affects neutrophil apoptosis, except for a report on heat shock-inducedapoptosis (46).

We then asked how body temperature regulates neutrophil apoptosis. Neutrophils have been considered to synthesize apoptosis-inhibitoryproteins, because addition of a protein synthesis inhibitor CHXto a culture medium of neutrophils has been reported to accelerateneutrophil apoptosis (31, 42). Thus we examined the involvementof protein synthesis in the lower temperature-induced suppressionof neutrophil apoptosis by incubating PECs for 18 h with or withoutCHX. CHX apparently accelerated apoptosis of neutrophils at 37°C,but apoptosis was not significantly changed for the control inthe absence of CHX compared with CHX at 35°C (Fig. 5), suggestingthat suppression of apoptosis at 35°C was caused in a proteinsynthesis-independent manner. Tsuchida et al. (42) reportedthat during 3 h incubation at 37°C, CHX did not enhance apoptosisof rat peritoneal exudate neutrophils stimulated by proteose peptoneinjection. The discrepancy between their and our results on CHXaction might be due to the difference of incubation time (3 vs.18 h). Addition of CHX as well as TNF- $alpha$ has been found to increasethe concentration of ceramide and its catabolite, sphingosine,a potent endogenous protein kinase C inhibitor in neutrophilsand other cells, and these second messengers are suggested toplay critical roles in processes of apoptosis (32). Becausethe rate of sphingosine formation has been demonstrated to increasewith a rise of temperature (from 30°C to 37°C) (36), the lowertemperature suppression of apoptosis might involve the interruptionof sphingosineformation.

Finally, we examined the effect of lower temperature on phagocytic function of the peritoneal neutrophils. A significant increasein lumisphere-ingesting neutrophils was obtained at 35°C, comparedwith 37°C (Table 2). TNF- $alpha$ tended to slightly increase the percentageat both 37°C and 35°C. The effect of temperature on phagocytosiswas examined earlier (15, 44, 45). Johansen et al. (15)reported that a moderate rise of temperature enhanced phagocytosisof some (but not all) kinds of bacterial organisms by human peripheralblood neutrophils, whereas Utoh and Harasaki (44) showed nochange of phagocytosis of serum-opsonized latex particles by humanand calf blood neutrophils below 42°C. The diverse results mightbe caused by obscurity in distinguishing phagocytosis from justattachment of the particles or organisms to cells. With the useof hydrophilic microsphere lumispheres, we recognized phagocytosismore easily and accurately by the difference in staining natureof the particles between intracellular and extracellular sites.As a possible mechanism by which neutrophil phagocytosis is upregulatedby the lower temperature, less production of ceramide might beagain related, because ceramide has been reported to inhibit neutrophilphagocytosis (38).

Taken together, we conclude that a rapid hypothermia occurs followed by neutrophil infiltration into peritoneum after injectionof inflammatory stimuli in mice. Endogenously released TNF- $alpha$ issuggested to regulate not only neutrophil infiltration, but alsobody temperature to maintain it slightly lower during neutrophilaccumulation and function. Lowered body temperature would suppressneutrophil apoptosis without protein synthesis and upregulateneutrophil phagocytic function both by its own effect and by negatingthe undesirable effect of TNF- $alpha$ on neutrophils. Further studiesare essential to investigate the effect of body temperature onother neutrophil function, such as superoxide and cytokine production,and the mechanisms for how temperature regulates neutrophil apoptosisandfunction.

Perspectives

As to the temperature effect on neutrophil function other than phagocytosis, previous studies have shown that a moderate (upto 40°C) rise of temperature results in rapid neutrophil migration;the opposite results were obtained with a hypothermic situation(45, 48). Because neutrophil accumulation, in our study, occurredduring restoration period of hypothermia, elevation of temperaturemay be involved in enhancement of neutrophil infiltration intoa casein-injected site. However, when anti-TNF was applied priorto casein injection, the number of peritoneal neutrophils wasdecreased despite a slight increase of body temperature. Thusit is so far uncertain to what extent the changes of temperatureactually influenced neutrophil infiltration in our inflammatorymodel.

Ensor et al. (8) have reported that high incubation temperature in a physiological range downregulates the expression ofTNF- $alpha$ in LPS-stimulated human macrophages derived from peripheralblood monocytes in vitro. Thus cytokine production of neutrophilsmight also be modulated by temperature. Moreover, on the basisof our data, it can be speculated that TNF- $alpha$ may prevent a suspensionof its own production by modulating a rise of body temperatureininflammation.

To investigate the temperature-induced intracellular events concerned in apoptosis or activation of neutrophils, concentrationsand/or activity of ceramide, protein kinase C, or other secondmessengers should beassessed.

	ACKNOWLEDGEMENTS

We appreciate Dr. Azumi Hamasaki for kind instruction of neutrophil purification from blood and Drs. Tomoko Tajima and ShunjiKozaki for agreeable offers of their experimental equipment. Wealso thank Seiko Ishihara for technical help in the TNF- $alpha$ bioassay.

	FOOTNOTES

This work was supported by the University-to-University Cooperative Research Program (08045058) by the Ministry of Education,Science, Sports, and Culture of Japan, Grant-in-Aid (09660324)for Scientific Research C by the Ministry of Education, Science,Sports, and Culture of Japan, and by the NaitoFoundation.

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.§1734 solely to indicate thisfact.

Address for reprint requests and other correspondence: Yukiko Kannan, Dept. of Veterinary Physiology, College of Agriculture, Osaka Prefecture University, 1-1 Gakuen-cho, Sakai, Osaka 599-8531, Japan (E-mail: kannan{at}vet.osakafu-u.ac.jp).

Received 26 January 1999; accepted in final form 11 August 1999.

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