Role of alpha 2-macroglobulin in fever and cytokine responses induced by lipopolysaccharide in mice

doi:10.1152/ajpregu.00746.2001

Role of $alpha$ ₂-macroglobulin in fever and cytokine responses induced by lipopolysaccharide in mice

Alexander V. Gourine¹, Valery N. Gourine¹, Yohannes Tesfaigzi², Nathalie Caluwaerts³, Fred Van Leuven³, and Matthew J. Kluger⁴

¹ Institute of Physiology, National Academy of Sciences of Belarus, Minsk 220725, Belarus; ² Lovelace Respiratory Research Institute, Albuquerque, New Mexico 87185; ³ Experimental Genetics Group, Department of Human Genetics, K. U. Leuven-Campus Gasthuisberg ON 06, B-3000 Leuven, Belgium; and ⁴ Medical College of Georgia, Augusta, Georgia 30912

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

$alpha$ ₂-Macroglobulin ( $alpha$ ₂M) is not only a proteinase inhibitor in mammals, but it is also a specific cytokine carrier that bindspro- and anti-inflammatory cytokines implicated in fever, includinginterleukin (IL)-1 $beta$ , IL-6, and tumor necrosis factor- $alpha$ (TNF- $alpha$ ).To define the role of $alpha$ ₂M in regulation of febrile and cytokineresponses, wild-type mice and mice deficient in $alpha$ ₂M ( $alpha$ ₂M $-$ / $-$ )were injected with lipopolysaccharide (LPS). Changes in body temperatureas well as plasma levels of IL-1 $beta$ , IL-6, and TNF- $alpha$ and hepaticTNF- $alpha$ mRNA level during fever in $alpha$ ₂M $-$ / $-$ mice were compared withthose in wild-type control mice. The $alpha$ ₂M $-$ / $-$ mice developed ashort-term markedly attenuated (ANOVA, P < 0.05) fever in responseto LPS (2.5 mg/kg ip) compared with the wild-type mice. At 1.5h after injection of LPS, the plasma concentration of TNF- $alpha$ , butnot IL-1 $beta$ or IL-6, was significantly lower (by 58%) in the $alpha$ ₂M $-$ / $-$ mice compared with their wild-type controls (ANOVA, P < 0.05).There was no difference in hepatic TNF- $alpha$ mRNA levels between $alpha$ ₂M $-$ / $-$ and wild-type mice 1.5 h after injection of LPS. These datasupport the hypotheses that 1) $alpha$ ₂M is important for the normaldevelopment of LPS-induced fever and 2) a putative mechanism of $alpha$ ₂M involvement in fever is through the inhibition of TNF- $alpha$ clearance.These findings indicate a novel physiological role for $alpha$ ₂M.

thermoregulation; proteinase inhibitor; interleukin; tumor necrosis factor; endotoxin

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

A REGULATED RISE in body temperature (T_b) or fever is an adaptive response of the organism to infection, injury, or traumaaimed at facilitating host resistance and slowing the growth ofthe pathogen (22). Considerable evidence indicates that manycirculating cytokines, such as interleukin (IL)-1 $beta$ , IL-6, tumornecrosis factor- $alpha$ (TNF- $alpha$ ), and others, act as endogenous pyrogensand are responsible for the induction and maintenance of feverby raising the "set point" for T_b regulation (22, 23). Onthe basis of the extensive evidence indicating crucial roles forIL-1 $beta$ , IL-6, TNF- $alpha$ , and other cytokines in the development ofthe febrile response, we hypothesized that any endogenous factorinvolved in the mechanisms of cytokine production or clearancemay also play an important role in fever. In the present study,we investigated the role in fever of $alpha$ ₂-macroglobulin ( $alpha$ ₂M), oneof the major plasma proteinase inhibitors in mammals and a specificcytokine carrier that binds and possibly regulates metabolismof cytokines implicated in fever, including IL-1 $beta$ , IL-6, and TNF- $alpha$ .

$alpha$ ₂M is a tetrameric glycoprotein (Mr ~750 kDa) present in human plasma at high concentrations (~2-4 mg/ml) and a proteinaseinhibitor that binds proteinases from all major classes (5,13, 34, 40). The major source of plasma $alpha$ ₂M is the hepatocyte(5, 34, 40); however, other cells including monocytes andmacrophages synthesize and secrete $alpha$ ₂M (3, 11, 21). Proteinasecleavage of the sensitive peptide bonds in the $alpha$ ₂M "bait region"induces a conformational change in the $alpha$ ₂M molecule, which irreversiblytraps the reacting proteinase (12, 34, 40). Conformationalchange of the $alpha$ ₂M also exposes binding sites for the $alpha$ ₂M receptor/low-densitylipoprotein receptor-related protein (LRP) (2, 36), whichis present on the surfaces of many different cell types, includinghepatocytes and macrophages (30). After binding to LRP, $alpha$ ₂M-proteinasecomplexes rapidly undergo endocytosis, indicating that LRP isresponsible for plasma clearance of conformationally modified $alpha$ ₂M (2, 13, 30, 36). $alpha$ ₂M in its native form does notbind LRP and has a prolonged half-life in circulation (34).

In humans, $alpha$ ₂M is constantly present in plasma, and the changes in plasma concentrations are moderate and rarely diagnosticfor any disease [for discussion, see Umans et al. (37)]. Thereis evidence, however, that lipopolysaccharide (LPS) may increaseas well as suppress (perhaps depending on the experimental conditions)production of $alpha$ ₂M by human monocytes and macrophages in vitro(3, 11, 21). These data indicate that during inflammationin humans, concentration of $alpha$ ₂M may change significantly on thetissue or cellular level, although alterations in plasma concentrationsarenegligible.

The ability to bind practically all cytokines, hormones, and growth factors is an intriguing feature of $alpha$ ₂M, and it indicatesthe potential role for this plasma protein in fever. Several studiesdemonstrated that $alpha$ ₂M is a specific cytokine carrier, which bindsmajor pro- and anti-inflammatory cytokines, such as IL-1 $beta$ (6,7), IL-6 (29), TNF- $alpha$ (9, 20, 42, 44), and others.Many cytokines can bind both native and proteinase-activated formsof $alpha$ ₂M (9). Importantly, binding of cytokines to the protease-activated $alpha$ ₂M does not affect the interaction of protease- $alpha$ ₂M-cytokine complexwith LRP (25). However, the functional role of $alpha$ ₂M in regulationof cytokine metabolism in vivo is far from clear. As it was discussedby LaMarre et al. (25) and Crookston et al. (9), the functionof $alpha$ ₂M as a cytokine-binding molecule is complicated due to thedifferent conformational states of $alpha$ ₂M. By functioning as a cytokinecarrier, $alpha$ ₂M in its native form may protect bound cytokines fromproteolytic degradation and, therefore, lengthen the plasma half-life.Most of the cytokines bound to the native $alpha$ ₂M retain their biologicalactivity [for review, see LaMarre et al. (25)]. On the otherhand, only proteinase-activated $alpha$ ₂M is recognized by LRP, andcytokines bound to the proteinase-activated $alpha$ ₂M may be targetedto the cells expressing LRP for endocytosis and rapid clearance[for discussion, see LaMarre et al. (25)].

In the present study, the role of $alpha$ ₂M in fever and cytokine responses induced by LPS was investigated using $alpha$ ₂M gene knockout( $alpha$ ₂M $-$ / $-$ ) mice developed by Umans et al. (37). Murine $alpha$ ₂M isa close homolog of human $alpha$ ₂M. Similar to human $alpha$ ₂M, murine $alpha$ ₂Mis a tetrameric glycoprotein with the molecular mass of ~720 kDaconstantly present in plasma in a concentration of ~2 mg/ml. Murine $alpha$ ₂M also inhibits proteases from all known classes and undergoesidentical human $alpha$ ₂M conformational changes upon reaction withprotease. Although during experimental inflammation in mice moderatechanges in plasma $alpha$ ₂M can be observed (1, 19), similar tohuman $alpha$ ₂M, murine $alpha$ ₂M is not an acute phase protein. Similaritiesbetween human and murine $alpha$ ₂Ms suggest that $alpha$ ₂M $-$ / $-$ mice representan adequate animal model for determining the role of this plasmaprotease inhibitor in fever and cytokine responses during experimentalinflammation.

We hypothesized that the role of $alpha$ ₂M in fever depends on whether this protease inhibitor facilitates or inhibits clearanceof the "major" endogenous pyrogens, e.g., IL-1 $beta$ , IL-6, or TNF- $alpha$ .In this study, LPS-induced fevers in $alpha$ ₂M $-$ / $-$ mice were comparedwith those in wild-type (WT) control mice. To investigate possibleinvolvement of cytokines, changes in plasma levels of IL-1 $beta$ , IL-6,and TNF- $alpha$ were determined during fever in $alpha$ ₂M $-$ / $-$ and $alpha$ ₂M WT mice.Because initial experiments showed that during fever plasma concentrationof TNF- $alpha$ , but not of IL-1 $beta$ or IL-6, was significantly lower inthe $alpha$ ₂M $-$ / $-$ mice compared with their WT controls, LPS-inducedchanges in hepatic TNF- $alpha$ mRNA levels in knockout and WT mice werestudied aswell.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Animals

All studies on conscious mice were conducted in facilities of the Lovelace Respiratory Research Institute, which is fullyaccredited by the Association for the Assessment and Accreditationof Laboratory Animal Care International, and were approved bythe Institutional Animal Care and Use Committee. Mice homozygousfor a null mutation in the $alpha$ ₂M gene were created by homologousrecombination in embryonic stem cells. The generation and characterizationof this strain have been described in detail (37, 38). Theoriginal $alpha$ ₂M $-$ / $-$ mice [C57BL × 129J random hybrids (37)] wereback-crossed into the C57BL/6J mouse strain for at least sevengenerations. Mice with a C57BL background of at least 98.5% wereobtained, which alleviated problems with differences in geneticbackground between experimental and control (C57BL/6J) mice. Age-,weight-, and sex-matched specific pathogen-free male C57BL/6Jmice (~3-4 mo of age, weighing 25-35 g) were purchased from JacksonLaboratories (Bar Harbor, ME) to serve as WT controls for allexperiments. On arrival, mice were housed one per cage in specificpathogen-free animal quarters, in a room maintained at a constanttemperature of 30 ± 1°C, a temperature within the thermoneutralzone of mice, and in a 12:12-h light-dark cycle with lights onat 0600. Drinking water and laboratory rodent chow were providedad libitum. At the end of the experiments, the animals were humanelykilled by an overdose of anesthetic (10% halothane in an airmixture).

Surgery

Mice were anesthetized with 4% halothane in an air mixture. An incision was made in the abdomen, and a miniature battery-operated,temperature-sensitive telemetry transmitter (model VMFH, Minimitter,Sunriver, OR) was placed into the abdominal cavity for continuousmonitoring of T_b and motor activity. The muscle and skin levelsof the abdomen were separately sutured. The wound area was swabbedwith Furacin, and the animals were returned to their cages wherethey were allowed to recover for at least 7 days. Experimentswere begun once each animal demonstrated a normal circadian variationin T_b.

T_b and Motor Activity Measurements

Core T_b (±0.1°C) and motor activity were monitored with implanted telemetry units (Minimitter). The animal's T_b was proportionalto the signal frequency emitted by the implanted transmitter.Any change in the position of the implanted transmitter relativeto the antenna under the cage was recorded as a pulse of activity.Recordings were made at 5-min intervals by use of a peripheralprocessor (Datacol III System, Minimitter) connected to an IBMpersonalcomputer.

Body Weight and Food Intake Measurements

Body weight and food intake were measured at 0900 each day on a top-loading balance with accuracy to ±0.1 g. Changes in bodyweight and food consumption were calculated by subtracting thevalues obtained for each successive 24-h time point after injectionfrom the value obtained immediately before injection. Thus changesin body weight and food intake were relative to preinjectionvalues.

Induction of Fever

Purified LPS (Escherichia coli endotoxin 0111:B4, Sigma Chemical, St. Louis, MO) was dissolved in pyrogen-free saline andinjected intraperitoneally at a dose of 2.5 mg/kg. Control micereceived an equivalent volume of sterile, pyrogen-free saline.Commercial-grade, steam-distilled turpentine (Sunnyside, Wheeling,IL) was injected intramuscularly into the left hindlimb at a volumeof 20 µl/mouse. Control animals were injected with 20 µl of sterilesaline intramuscularly into the same injection site. All micewere anesthetized with halothane during the injectionprocedure.

ELISA

Blood for cytokine analysis was collected from anesthetized (4% halothane in air mixture) mice by cardiac puncture. Bloodwas drawn into heparinized syringes, and plasma was separatedby centrifugation (12,000 rpm, 5 min, 20°C) of the freshly drawnblood and stored at $-$ 20°C until assayed. Cytokines were not separatedfrom the plasma carrier proteins before assays. IL-1 $beta$ , IL-6, andTNF- $alpha$ concentrations in plasma were measured using mouse IL-1 $beta$ (R&D Systems, Minneapolis, MN), IL-6 (Endogen, Woburn, MA), andTNF- $alpha$ (Endogen) immunoassay kits according to manufacturer's instructions.These assays detect IL-1 $beta$ , IL-6, and TNF- $alpha$ at concentrations aslow as 3.0, 7.0, and 10.0 pg/ml,respectively.

RT-PCR

RNA was isolated from the livers of $alpha$ ₂M $-$ / $-$ and WT mice treated with either LPS or saline using phenol-free total RNA isolationkits (Ambion, Austin, TX) according to the manufacturer's manual.First-strand cDNA was synthesized from 3 µg of total RNA primedwith poly dT₂₁ by using the Superscript Preamplifications System(Life Technologies, Gaithersburg, MD). To eliminate the possibilityof false positives by residual genomic DNA, samples were treatedwith DNase (Roche Biochemicals, Indianapolis, IN). Primers formurine TNF- $alpha$ and $beta$ -actin were purchased from Stratagene (La Jolla,CA) and used at a concentration of 1 µM. After cDNA synthesis,PCR reactions were performed parallel in 50-µl reaction volumes.PCR amplification reaction included a 5-min denaturation at 94°Cand a 5-min annealing at 60°C, followed by 35 cycles of 1.5 minat 72°C, 45 s at 94°C, and 45 s at 60°C, with a final extensionof 10 min at 72°C. Primer pair for TNF- $alpha$ was 5'-ATGAGCACAGAAAGCATGATC-3'(sense) and 5'-TACAGGCTTGTCACTCGAATT-3' (antisense). Twenty microlitersof amplified products were analyzed by electrophoresis in a 2%agarose gel. Each RT-PCR assay was repeated at least once forconfirmation. The bands of the PCR products on the agarose gelwere quantified via densitometry using a Fluor-S MAX Imager andthe Quantity One software (BioRad, Hercules, CA). The band intensitiesof TNF- $alpha$ were normalized with the corresponding band intensitiesfor $beta$ -actin.

Experimental Design

Experiment 1. LPS-induced fever in $alpha$ ₂M gene knockout mice. Mice were assigned to one of four groups: $alpha$ ₂M $-$ / $-$ mice treated with either LPS (n = 16) or pyrogen-free saline (n = 11) and $alpha$ ₂M WT mice injected with either LPS (n = 20) or pyrogen-freesaline (n = 14). All injections were performed at 0900. T_b andmotor activity were monitored for 3 h before and 48 h after LPSor saline injections. Body weight and food intake were measuredup to 4 days postinjection in six $alpha$ ₂M $-$ / $-$ mice and eight WT micetreated with LPS and in six $alpha$ ₂M $-$ / $-$ mice and eight WT mice injectedwithsaline.

Experiment 2. Turpentine-induced fever in $alpha$ ₂M gene knockout mice. To test the ability of $alpha$ ₂M $-$ / $-$ mice to mount a normal thermogenic response, we compared fevers in $alpha$ ₂M $-$ / $-$ and WT mice developedduring localized inflammation (induced by turpentine injection).Mice were assigned to one of four groups: $alpha$ ₂M $-$ / $-$ mice treatedwith either turpentine (n = 4) or pyrogen-free saline (n = 3)and $alpha$ ₂M WT mice injected with either turpentine (n = 5) or pyrogen-freesaline (n = 4). Because of the limited availability of $alpha$ ₂M $-$ / $-$ mice for our studies, all $alpha$ ₂M $-$ / $-$ and WT mice were those previouslyused in experiment 1. To circumvent any effect of previous injections,only those mice previously injected with sterile saline were used.All injections were performed between 0900 and 1000. T_b was monitoredfor 48 h after turpentine or salineinjections.

Experiment 3. LPS-induced changes in plasma levels of IL-1 $beta$ , IL-6, and TNF- $alpha$ in $alpha$ ₂M gene knockout mice. Plasma concentrations of cytokines were measured at 1.5, 4, and 27 h after injection of LPS because of the following reasons.In mice and rats, at 1.5 h after the LPS challenge, high plasmaconcentrations of both IL-6 and TNF- $alpha$ are observed, whereas TNF- $alpha$ level is at or near its peak (8, 41). In addition, resultsof experiment 1 showed that, at 1.5 h after LPS injections, T_bis significantly lower in the $alpha$ ₂M $-$ / $-$ mice compared with theirWT controls. At 4 h after LPS treatment, both moderate increasein plasma concentration of IL-1 $beta$ and still high plasma level ofIL-6 are observed, whereas plasma TNF- $alpha$ concentration decreasesto control levels (8). Because in some studies in mice feverwas observed to last up to 30 h after LPS injections (26, 27),we also measured plasma levels of cytokines at 27 h after LPSchallenge (at the middle of the next day after LPS injections).The design for experiment 1 was used. Mice were placed into oneof four groups: LPS injected $alpha$ ₂M $-$ / $-$ (n = 5), saline injected $alpha$ ₂M $-$ / $-$ (n = 3), LPS injected WT (n = 6), or saline injected WT(n = 3). Mice were injected with either LPS (2.5 mg/kg) or salinebetween 0900 and 1000. Blood for cytokine analysis was collectedfrom anesthetized (4% halothane in air mixture) $alpha$ ₂M and WT miceby cardiac puncture at 1.5, 4, and 27 h after the injections.Immediately after the collection, plasma was separated by centrifugationand stored at $-$ 20°C untilassayed.

Experiment 4. LPS-induced changes in hepatic TNF- $alpha$ mRNA levels in $alpha$ ₂M gene knockout mice. There is evidence that, in response to LPS challenge, different hepatic cells are capable of TNF- $alpha$ expression, whereas Kupffercells are the predominant source of circulating TNF- $alpha$ (8, 18,28). Therefore, to compare LPS-induced production of TNF- $alpha$ in $alpha$ ₂M $-$ / $-$ and WT mice, hepatic TNF- $alpha$ mRNA levels were measured.Taking into account that the decay in hepatic TNF- $alpha$ mRNA levelis slow [hepatic TNF- $alpha$ mRNA level only slightly decreases between1 and 3 h after LPS challenge (33)], whereas half-life of TNF- $alpha$ protein in circulation is very short (4, 10), and becauseof the limited availability of the $alpha$ ₂M $-$ / $-$ mice for our studies,hepatic TNF- $alpha$ mRNA levels were measured at the same time as theplasma TNF- $alpha$ concentration, i.e., 1.5 h after injections of LPSor saline. The design for experiment 1 was used. Animals usedin experiment 3 for blood collection were also used to harvestliver tissue. Immediately after blood collection, a portion ofthe liver was removed, immediately frozen in liquid nitrogen,and stored at $-$ 80°C until total RNA extraction and assay for TNF- $alpha$ mRNAlevels.

Statistical Analysis

Data are reported as means ± SE. Experimental groups were compared using two-way ANOVA followed by the post hoc Fisher's test.A value of P < 0.05 was considered to besignificant.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Experiment 1. LPS-induced fever in $alpha$ ₂M gene knockout mice. The febrile response of $alpha$ ₂M $-$ / $-$ and WT mice is shown in Fig. 1. The injection procedure caused profound short-term, stress-inducedrises in T_b. Interestingly, the magnitude of this initial stress-inducedrise in T_b was significantly higher in WT mice compared with $alpha$ ₂M $-$ / $-$ mice, regardless of whether they were injected with LPS orsaline (Fig. 1). Both groups of mice injected with saline returnedto the normal level of T_b within 90 min with no difference between $alpha$ ₂M $-$ / $-$ (Fig. 1, $black-triangle$ ) and WT (Fig. 1, $triangle$ ) animals. As shown in Fig.1, $alpha$ ₂M $-$ / $-$ mice developed short-lasted and markedly attenuatedfever in response to LPS compared with their WT counterparts. $alpha$ ₂M WT mice responded to LPS with an ~0.9°C fever that began 90min postinjection and lasted up to 7 h (Fig. 1, $open circle$ ). In $alpha$ ₂M $-$ / $-$ mice, LPS induced a short-term ~0.6°C rise in T_b, which returnedto the values observed in $alpha$ ₂M $-$ / $-$ and WT mice treated with saline4 h after the injection (Fig. 1, ). Thus febrile response toLPS in $alpha$ ₂M $-$ / $-$ mice was shorter by 3 h compared with fever in $alpha$ ₂M WT mice. There was no difference in T_b between $alpha$ ₂M $-$ / $-$ andWT mice treated with either LPS or saline 9-48 h after the injections(data not shown).

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Fig. 1. Effect of lipopolysaccharide (LPS; 2.5 mg/kg) or pyrogen-free saline (equivalent volume) injected intraperitoneally on body temperature in $alpha$ ₂-macroglobulin gene knockout ( $alpha$ ₂M $-$ / $-$ ) and wild-type (WT) mice. Data are presented as means ± SE. Numbers in parentheses indicate sample sizes. Arrowhead indicates time of LPS and saline injections. $dagger$ Significant difference between $alpha$ ₂M $-$ / $-$ and WT mice injected with LPS; between $alpha$ ₂M $-$ / $-$ and WT mice injected with saline, P < 0.05. * Significant difference between LPS-injected $alpha$ ₂M $-$ / $-$ and WT mice, P < 0.05.

During the 24-h period after injection, LPS induced a significant reduction in body weight (Fig. 2A) and food intake (Fig.2B) in $alpha$ ₂M $-$ / $-$ and WT mice relative to saline-injected controls.There was no significant difference in body weight and food intakebetween $alpha$ ₂M $-$ / $-$ and WT mice injected with LPS (Fig. 2). Injectionof LPS also resulted in a complete suppression of locomotor activityin both $alpha$ ₂M $-$ / $-$ and WT mice (data not shown). However, changesin activity in response to LPS did not differ between $-$ / $-$ andWT mice.

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Fig. 2. Effect of LPS (2.5 mg/kg) or pyrogen-free saline (equivalent volume) injected intraperitoneally on change in body weight (A) and food intake (B) in $alpha$ ₂M $-$ / $-$ and WT mice. Data are presented as means ± SE. Numbers in parentheses indicate sample sizes.

Experiment 2. Turpentine-induced fever in $alpha$ ₂M gene knockout mice. Local tissue injury following turpentine administration was accompanied by significant fever on the next day. There was nodifference in turpentine-induced changes in T_b between $alpha$ ₂M $-$ / $-$ and WT mice (Fig. 3).

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Fig. 3. Effect of turpentine (20 µl) or pyrogen-free saline (20 µl) injected intramuscularly into the left hindlimb on body temperature in $alpha$ ₂M $-$ / $-$ and WT mice. Data are presented as means ± SE. Numbers in parentheses indicate sample sizes. Arrowhead indicates time of LPS and saline injections. Between 22 and 31 h after the injections, body temperature in $alpha$ ₂M $-$ / $-$ and WT mice treated with turpentine was significantly (P < 0.05) higher than in $alpha$ ₂M $-$ / $-$ and WT mice injected with saline.

Experiment 3. LPS-induced changes in plasma levels of IL-1 $beta$ , IL-6, and TNF- $alpha$ in $alpha$ ₂M gene knockout mice. Plasma IL-1 $beta$ , IL-6, and TNF- $alpha$ levels were measured in $alpha$ ₂M $-$ / $-$ and WT mice at 1.5, 4, and 27 h following injection of LPS orsaline (Fig. 4). At all time points tested following injectionof saline, $alpha$ ₂M $-$ / $-$ and WT mice showed low plasma IL-1 $beta$ , IL-6,and TNF- $alpha$ concentrations that did not significantly differ betweengroups (Fig. 4). Although plasma levels of IL-1 $beta$ , IL-6, and TNF- $alpha$ in $alpha$ ₂M $-$ / $-$ and WT mice treated with saline were low, they wereabove the detection limits of the assays and were included inthe statistical analysis. These baseline values of plasma IL-6and TNF- $alpha$ concentrations are not adequately presented in Fig.4, B and C, due to the large scale of the y-axis. The values ofplasma TNF- $alpha$ concentrations in $alpha$ ₂M $-$ / $-$ and WT mice 1.5 h aftersaline injection are given in the text below, as it is importantfor the comparison with the values of the TNF- $alpha$ concentrationsinduced by LPS challenge.

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Fig. 4. Effect of LPS (2.5 mg/kg) or pyrogen-free saline (equivalent volume) injected intraperitoneally on plasma levels of interleukin (IL)-1 $beta$ (A), IL-6 (B), and tumor necrosis factor- $alpha$ (TNF- $alpha$ ; C) in $alpha$ ₂M $-$ / $-$ and WT mice. Plasma IL-1 $beta$ , IL-6, and TNF- $alpha$ concentrations were measured at 1.5, 4, and 27 h following injection of LPS or saline. Data are presented as means ± SE. Numbers in parentheses indicate sample sizes. At 4 h after the injections, IL-1 $beta$ levels in plasma of $alpha$ ₂M $-$ / $-$ and WT mice treated with LPS were significantly (P < 0.05) higher than in plasma of $alpha$ ₂M $-$ / $-$ and WT mice injected with saline (A). At 1.5 and 4 h after the injections, IL-6 levels in plasma of $alpha$ ₂M $-$ / $-$ and WT mice treated with LPS were significantly (P < 0.05) higher than in plasma of $alpha$ ₂M $-$ / $-$ and WT mice injected with saline (B). * Significant difference in plasma TNF- $alpha$ concentration between $alpha$ ₂M $-$ / $-$ and WT mice injected with LPS, P < 0.05.

Treatment with LPS resulted in a moderate but significant elevation in plasma concentration of IL-1 $beta$ in $alpha$ ₂M $-$ / $-$ and WT mice4 h after the injection (Fig. 4A). There was no significant differencein plasma IL-1 $beta$ concentrations between $-$ / $-$ and WT mice injectedwith LPS (Fig. 4A).

LPS injection resulted in a profound early elevation in plasma levels of IL-6 (Fig. 4B). A high concentration of IL-6 wasobserved in the plasma of $alpha$ ₂M $-$ / $-$ and WT mice 1.5 and 4 h afterLPS injection (Fig. 4B). However, there was no significant differencein plasma IL-6 concentrations between $alpha$ ₂M $-$ / $-$ and WT mice injectedwith LPS at either time point tested (Fig. 4B).

Ninety minutes after saline injection, plasma concentrations of TNF- $alpha$ in $alpha$ ₂M $-$ / $-$ and WT mice were 41 ± 28 and 55 ± 6 pg/ml,respectively (P > 0.05). LPS challenge resulted in a significantearly elevation in the plasma level of TNF- $alpha$ (Fig. 4C). Ninetyminutes after LPS injection, plasma concentration of TNF- $alpha$ wassignificantly lower in $alpha$ ₂M $-$ / $-$ mice compared with WT controls(5,427 ± 1,330 vs. 12,817 ± 1,477 pg/ml, P = 0.0037; Fig. 4C).By 4 h after LPS injection, plasma TNF- $alpha$ concentration decreasedto control levels (within the range of 40-90 pg/ml), and therewas no difference between $alpha$ ₂M $-$ / $-$ and WT mice (Fig. 4C).

Experiment 4. LPS-induced changes in hepatic TNF- $alpha$ mRNA levels in $alpha$ ₂M gene knockout mice. TNF- $alpha$ mRNA levels in the liver were determined in $alpha$ ₂M $-$ / $-$ and WT mice at 1.5 h following injection of LPS or saline (whenthe difference in plasma concentration of TNF- $alpha$ between $alpha$ ₂M $-$ / $-$ and WT mice was observed). $alpha$ ₂M $-$ / $-$ and WT mice injected with salineshowed low TNF- $alpha$ (Fig. 5) mRNA levels that did not significantlydiffer between groups. LPS led to a significant elevation in hepaticTNF- $alpha$ (Fig. 5) mRNA levels at 1.5 h postinjection. There was nosignificant difference in hepatic TNF- $alpha$ (Fig. 5) mRNA levels between $alpha$ ₂M $-$ / $-$ and WT mice 1.5 h after injection of LPS.

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Fig. 5. A: detection of TNF- $alpha$ and $beta$ -actin mRNAs by RT-PCR from RNA isolated from the liver of $alpha$ ₂M $-$ / $-$ and WT mice 1.5 h after intraperitoneal injection of LPS (2.5 mg/kg) or pyrogen-free saline. B: quantification of the band intensities normalized for the housekeeping gene, $beta$ -actin, showed significant increases of hepatic TNF- $alpha$ mRNA levels in $alpha$ ₂M $-$ / $-$ and WT mice treated with LPS compared with their saline-injected counterparts. Samples of the hepatic RNA from 5 $alpha$ ₂M $-$ / $-$ mice injected with LPS, 3 $alpha$ ₂M $-$ / $-$ mice injected with saline, 6 WT mice injected with LPS, and 3 WT mice injected with saline were analyzed in 2 separate assays. Data are presented as means ± SE. * Significant difference between $alpha$ ₂M $-$ / $-$ mice injected with LPS and saline; between WT mice injected with LPS and saline, P < 0.05.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In the present study, the role of $alpha$ ₂M in LPS-induced fever and cytokine responses was studied. $alpha$ ₂M $-$ / $-$ mice developed a short-termmarkedly attenuated fever in response to LPS, suggesting thatthis plasma protease inhibitor is essential for normal developmentof LPS-induced fever in mice. There was no difference in plasmalevels of IL-1 $beta$ and IL-6 between $alpha$ ₂M $-$ / $-$ and WT mice after injectionof LPS. Plasma concentration of TNF- $alpha$ shortly after LPS challengewas significantly lower in the $alpha$ ₂M $-$ / $-$ mice compared with theirWT counterparts. No difference in the hepatic TNF- $alpha$ mRNA levelsbetween $alpha$ ₂M $-$ / $-$ and WT mice treated with LPS suggests augmentedclearance of TNF- $alpha$ in $alpha$ ₂M $-$ / $-$ mice. No difference in fever between $alpha$ ₂M $-$ / $-$ and WT mice following turpentine injection suggests that $alpha$ ₂M $-$ / $-$ mice can increase their T_b in response to other stimulito the same extent as the control animals, indicating that $alpha$ ₂Mdeficiency does not impair these animals' ability to mount anadequate thermogenic response. In view of the latter, an interestingobservation is that the magnitude of the initial stress-inducedrise in T_b (evoked by the injection procedure) was significantlylower in $alpha$ ₂M $-$ / $-$ mice compared with WT mice, regardless of whetherthey were injected with LPS or saline (Fig. 1). This observationmay suggest that $alpha$ ₂M is also involved in the mechanisms of thedevelopment of stress-induced fever, and, to study the mechanismsof this involvement, the data have to be confirmed in "controlled"experiments, such as those in which animals are exposed to anidentical novelenvironment.

Successful targeting of the $alpha$ ₂M gene and generation of the $alpha$ ₂M $-$ / $-$ mice (37, 38) provided a valuable tool to dissect therole of this protease inhibitor in febrile and cytokine responsesinduced by LPS. Unfortunately, this transgenic model is not ideal,because mouse plasma, unlike plasma of humans and other mammals,contains two different types of $alpha$ -macroglobulins: the tetrameric $alpha$ ₂M and the monomeric or single-chain murinoglobulins, the invivo function of which is still unclear [for detailed discussion,see Umans et al. (37)]. Although levels of murinoglobulins inthe plasma of adult nonpregnant $alpha$ ₂M $-$ / $-$ mice are unchanged comparedwith WT animals (37), we cannot completely exclude the possibilitythat, during development of the inflammatory response inducedby either LPS or turpentine, murinoglobulins may, in part, functionallyreplace $alpha$ ₂M in the $alpha$ ₂M $-$ / $-$ mice. Therefore, as in any experimentinvolving gene knockout animals, caution should have been takenin the interpretation of the obtaineddata.

We reported recently that human $alpha$ ₂M induces moderate fever (~0.5°C) in mice when injected intravenously in amounts similarto or even smaller than those observed during the developmentof the systemic inflammatory response (14). Furthermore, itwas shown that 1 h after intravenous injection, human $alpha$ ₂M inducesmoderate (smaller compared with LPS induced) but significant increasein plasma bioactivity of TNF- $alpha$ (14), suggesting that TNF- $alpha$ maymediate the pyrogenic effect of human $alpha$ ₂M in mice. It is possiblethat exogenous $alpha$ ₂M either inhibits rapid degradation of TNF- $alpha$ ,which is constitutively produced under basal "nonpathological"conditions (28, 33), or stimulates TNF- $alpha$ synthesis, or both.Although the mechanisms of the increase in plasma TNF- $alpha$ levelinduced by intravenous injection of exogenous $alpha$ ₂M in mice haveto be investigated, these findings coincide with the results ofthe present study, and, taken together, they suggest an importantrole for $alpha$ ₂M in the mechanisms of feverdevelopment.

The present data also correlate well with the observations of Umans et al. (37), who reported that $alpha$ ₂M $-$ / $-$ mice are resistantto the lethal effects of LPS. However, although LPS-induced feverwas lower in $alpha$ ₂M $-$ / $-$ mice, the other "signs" of sickness syndrome,i.e, body weight loss, decrease in food intake, and decrease inmotor activity, were identical to those in control WT mice (Fig.2). Thus, in terms of induction of anorexia and lethargy, $alpha$ ₂M $-$ / $-$ mice are equally sensitive to LPS. These unexpected observationssuggest that although playing an important role in the developmentof fever, $alpha$ ₂M probably is not involved in anorexia and lethargyinduced by LPS in mice. In view of the results obtained in thepresent study, indicating that $alpha$ ₂M is likely to be involved inLPS-induced fever through the inhibition of TNF- $alpha$ clearance, thesedata are in agreement with the results obtained in the TNF double-receptorknockout mice, showing that TNF- $alpha$ does not mediate LPS-inducedanorexia and lethargy (27). However, one should apply some cautionin interpretation of our results. It is possible, due to inherentredundancy in hormone/cytokine action, that in both cases knockoutmice compensate for removal of one gene by increased action ofanother in the regulation of some aspects of the acute phase responsetoLPS.

Although $alpha$ ₂M is not an acute phase protein in mice (unlike in rats and some other species), during experimental inflammation,moderate changes in plasma levels of murine $alpha$ ₂M do occur (1,19). LPS in a dose of 20 µg/mouse (~1.0 mg/kg) induced a significantincrease in plasma $alpha$ ₂M concentration 24 and 48 h after intraperitonealinjection (19). It is impossible to compare these results withthe data obtained in our study, because different strains of miceand doses of LPS were used. However, the study of Isaac et al.(19) is important to this discussion as it shows that LPS caninduce $alpha$ ₂M production in mice. Interesting data were obtainedby LaMarre et al. (24), who showed that expression of LRP inmurine macrophages can be markedly decreased by LPS. These dataindicate that LPS is a natural regulator of the $alpha$ ₂M/LRP system:it can increase $alpha$ ₂M production and, at the same time, suppressthe expression of the $alpha$ ₂Mreceptor.

We hypothesized initially that the effect of $alpha$ ₂M on the febrile response depends on whether this protease inhibitor facilitatesor inhibits clearance of the "major" endogenous pyrogens, e.g.,IL-1 $beta$ , IL-6, or TNF- $alpha$ . This hypothesis was supported by the vastamount of literature indicating that plasma $alpha$ ₂M is a broad-spectrumprotease inhibitor and a cytokine-binding protein and carrierat the same time (5-7, 9, 13, 20, 25, 29, 42, 44).Extrapolation from in vitro studies suggested that depending onthe conformational state of the $alpha$ ₂M molecule, its function inregulation of cytokine metabolism and, therefore, thermoregulatoryfebrile response could be different. As discussed by LaMarre etal. (25) and mentioned earlier in text, $alpha$ ₂M in its native formmay protect bound cytokine from proteolytic degradation by functioningas a cytokine carrier and, therefore, lengthen its plasma half-life.On the other hand, proteinase-activated $alpha$ ₂M (that is recognizedby LRP) may play an important role in the processes of cytokineclearance.

Results of the present study suggest an augmented rate of TNF- $alpha$ clearance in $alpha$ ₂M $-$ / $-$ mice. Several studies in vitro demonstratedbinding of TNF- $alpha$ to native and protease-activated $alpha$ ₂M (9, 20,42, 44). It has been shown that neither native nor protease-activated $alpha$ ₂M reduces biological activity of TNF- $alpha$ (44). Although TNF- $alpha$ binds native $alpha$ ₂M with lower affinity than protease-activated $alpha$ ₂M,we hypothesize that under most conditions and particularly duringLPS-induced fever, native $alpha$ ₂M is more important in regulatingTNF- $alpha$ clearance than protease-modified $alpha$ ₂M. First, our data suggestan augmented clearance of TNF- $alpha$ in $alpha$ ₂M $-$ / $-$ mice. If protease-activated $alpha$ ₂M played a significant role in LRP-mediated TNF- $alpha$ clearancein vivo, we would expect to observe the opposite (i.e., higherplasma concentration of TNF- $alpha$ in $alpha$ ₂M $-$ / $-$ mice compared with WTcontrols). Second, native $alpha$ ₂M is the predominant form of $alpha$ ₂M presentin the plasma and in the extravascular microenvironments. In contrast,protease-activated $alpha$ ₂M under most conditions is present only attrace levels. We hypothesize that native $alpha$ ₂M, as a broad-spectrumprotease inhibitor, protects bound TNF- $alpha$ from proteolytic degradationand, therefore, lengthens its plasma half-life. This conclusionis supported by the evidence that TNF- $alpha$ is efficiently destroyedby proteases released from activated polymorphonuclear neutrophilsand that after proteolytic cleavage, TNF- $alpha$ fragments lack anyTNF- $alpha$ -like cytotoxic activity (31, 39).

Our data do not support the observations of Hochepied at al. (16), who showed an identical rate of clearance of injectedTNF- $alpha$ in $alpha$ ₂M $-$ / $-$ and WT mice. Both data are difficult to reconcile,especially because the same mice were used in both studies. Presumably,the clearance mechanisms of injected TNF- $alpha$ are to some extentdifferent from those of LPS-induced, endogenously produced TNF- $alpha$ .The latter could be significantly affected by other responses(physiological and humoral) induced by LPS and not mimicked byinjection of TNF- $alpha$ alone.

The lack of a difference in plasma levels of IL-1 $beta$ and IL-6 between $alpha$ ₂M $-$ / $-$ and WT mice after injection of LPS does not supportthe hypothesis that fever in $alpha$ ₂M $-$ / $-$ mice is attenuated due todecreased production or increased clearance of IL-1 $beta$ or IL-6.These data were somewhat unexpected in view of the evidence obtainedin experiments in vitro suggesting that $alpha$ ₂M is one of the majorIL-1 $beta$ - and IL-6-binding plasma proteins (6, 7, 29). Dataobtained in the present study reveal the limitations of a directextrapolation from these in vitro studies and suggest that $alpha$ ₂Mmay not play a significant role in the regulation of IL-1 $beta$ andIL-6 clearance during LPS-induced fever inmice.

Although the precise role of TNF- $alpha$ in fever is still unresolved, we propose that the putative mechanism of $alpha$ ₂M involvementin LPS-induced fever is through the inhibition of TNF- $alpha$ clearance.Indeed, depending on the experimental conditions and animal species(and probably also strains) used, this cytokine can act as anendogenous pyrogen as well as an endogenous antipyretic. Injectionor infusion of TNF- $alpha$ appears to induce fever in several species(for review, see Refs. 22, 23, 35). When the actions ofendogenous TNF- $alpha$ were blocked experimentally, this cytokine showedantipyretic properties in rats and mice and pyrogenic activityin rats, rabbits, guinea pigs, and humans (for recent reviews,see Refs. 15, 32, 35). The following arguments supportingthe above hypothesis should be mentioned: 1) TNF- $alpha$ is a majorproinflammatory cytokine, and its lower plasma levels indicatea smaller systemic inflammatory response. 2) We observed thatintravenous injection of recombinant murine TNF- $alpha$ (1 µg) inducesmoderate (1°C) fever in C57BL/6J mice (A.V. Gourine and M.J. Kluger,unpublished observations) in mice of the same strain that wasused in the present study. 3) It appears that, when TNF- $alpha$ is notinvolved in fever, $alpha$ ₂M is also without effect. Neither TNF- $alpha$ (27)nor $alpha$ ₂M is involved in fever induced by local inflammation (injectionof turpentine). 4) Roth et al. (32) recently reported that inguinea pigs neutralization of TNF- $alpha$ by treating the animals withits type 1 soluble receptor significantly attenuates the secondphase of the LPS-induced febrile response without affecting itsinitial phase. Interestingly, neutralization of TNF- $alpha$ by its type1 soluble receptor affects the development of fever in guineapigs in the same way as inactivation of the $alpha$ ₂M gene affects feverin mice, i.e., resulting in a marked attenuation of the late phaseof the febrile response without markedly affecting the initialphase.

In conclusion, results of the present study suggest that $alpha$ ₂M is important for the normal development of LPS-induced feverin mice and that putative mechanism of $alpha$ ₂M involvement in LPS-inducedfever is through the inhibition of TNF- $alpha$ clearance. We speculatethat $alpha$ ₂M serves as an inhibitor of proteinases (e.g., elastase)responsible for rapid degradation of TNF- $alpha$ and, possibly, of otherpyrogenic cytokines (but not IL-1 $beta$ or IL-6).

Perspectives

Protease inhibitors, $alpha$ ₂M in particular, are often considered nonspecific defense molecules, with the function of protectingtissues from unwanted proteases released by pathogenic microorganismsor from the dying cells of the host. Data obtained in the presentstudy indicate a novel physiological role for plasma $alpha$ ₂M. We identified $alpha$ ₂M as an endogenous factor involved in regulation of TNF- $alpha$ clearanceand essential for the normal development of fever in responseto bacterial endotoxin. Because $alpha$ ₂M has several diverse properties,it is possible that regulation of TNF- $alpha$ clearance is not the onlymechanism by which this protease inhibitor modulates the febrileresponse. For example, it has been shown that $alpha$ ₂M is able to induceprostaglandin E₂ (17) and nitric oxide synthesis (43), suggestingthat another putative mechanism of $alpha$ ₂M involvement in fever couldbe via stimulation of prostaglandin E₂ and (or) nitric oxide production.Also, $alpha$ ₂M is synthesized in the brain primarily by astrocytes,and expression of its receptor (LRP) has been identified in neuronsand astrocytes in the central nervous system (30), suggestingthat $alpha$ ₂M can act directly in the brain to modulate fever inducedby LPS. Further studies of the possible mechanisms of $alpha$ ₂M involvementin fever may lead to the development of new approaches (basedon modifing activity of this major protease inhibitor) of modulatingfebrile and inflammatory responses, which is particularly importantin cases when overzealous fever or (and) excessive productionof proinflammatory cytokines is harmful for thehost.

	ACKNOWLEDGEMENTS

We thank K. Rudolph and J. Littell for contribution to the pilot study, Dr. W. Kozak for helpful discussions, and P. Bradleyfor editing of themanuscript.

	FOOTNOTES

This study was supported by Grant RO3 TW00992-01 from the Fogarty International Center (FIC), National Institutes of Health(NIH), and by NIH Grant AI-27556 to M. J.Kluger.

Contents of the paper are solely the responsibility of the authors and do not necessarily represent the official views ofthe NIH or theFIC.

Address for reprint requests and other correspondence: A. V. Gourine, Dept. of Physiology, Royal Free and Univ. College MedicalSchool, Rowland Hill St., London NW3 2PF, UK (E-mail: a.gourine{at}rfc.ucl.ac.uk).

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.Section 1734 solely to indicate thisfact.

First published March 7, 2002;10.1152/ajpregu.00746.2001

Received 17 December 2001; accepted in final form 4 March 2002.

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Role of 2-macroglobulin in fever and cytokine responses induced by lipopolysaccharide in mice

Role of $alpha$ ₂-macroglobulin in fever and cytokine responses induced by lipopolysaccharide in mice