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Leptin Corrects Host Defense Defects after Acute Starvation in Murine Pneumococcal Pneumonia

Departments of Environmental Health Sciences, Internal Medicine, and Microbiology and Immunology, University of Michigan; and VA Medical Center, Ann Arbor, Michigan

Correspondence and requests for reprints should be addressed to Peter Mancuso, Ph.D., University of Michigan, 1420 Washington Heights, Department of Environmental Health Sciences SPH II, Ann Arbor, MI 48109-2029. E-mail: pmancuso{at}umich.edu

	ABSTRACT

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Rationale: Leptin is an adipocyte-derived hormone that declines dramatically during fasting and plays a pivotal role in the neuroendocrine response to starvation. Previously, we employed leptin-deficient (ob/ob) mice to identify an important role for leptin in the host defense against Klebsiella pneumonia.

Objectives: To assess the effects of fasting on the innate immune response against pneumococcal pneumonia and to determine the effects of maintaining circulating leptin levels on host defense in fasted mice.

Methods: C57BL/6 mice were either fed ad libitum or fasted for 48 h and given an intraperitoneal injection of saline or recombinant leptin (1 µg/g of body weight) twice daily for 48 h before bacterial challenge. Mice were challenged with 10⁵ cfu of Streptococcus pneumoniae via the intranasal route.

Measurements and Main Results: Lung homogenate S. pneumoniae burden was nearly 20-fold greater in the fasted as compared with fed mice. The impairment in bacterial clearance observed in fasted animals was associated with reduced bronchoalveolar lavage neutrophil counts and interleukin-6 and macrophage inflammatory protein-2 levels. Alveolar macrophages from fasted animals also exhibited defective phagocytosis and killing of S. pneumoniae and reduced calcium-ionophore–stimulated leukotriene B₄ synthesis in vitro. In contrast, the provision of exogenous leptin to fasted animals restored bacterial clearance, bronchoalveolar lavage levels of neutrophils and cytokines, alveolar macrophage bacterial killing, and leukotriene B₄ synthesis.

Conclusions: These results suggest that reduced leptin levels substantially contribute to the suppression of pulmonary antibacterial host defense during starvation and that administration of this adipokine may be of therapeutic benefit clinically.

Key Words: leptin • malnutrition • pneumonia • Streptococcus pneumoniae

Streptococcus pneumoniae colonizes the upper respiratory tract of susceptible hosts and is the most common cause of community-acquired pneumonia, accounting for 175,000 hospitalizations per year in the United States alone (1, 2). Individuals who are particularly susceptible to pneumococcal pneumonia include the critically ill and those with chronic diseases, such as alcoholism, chronic obstructive pulmonary disease, and cancer (3). These same individuals frequently become energy malnourished and this contributes to their increased susceptibility to infection (4–7). The mechanisms responsible for impaired innate immune responses against bacterial infections arising from energy malnutrition are poorly understood.

Acute energy malnutrition, induced by fasting, initiates a number of physiologic adaptations that conserve energy stores at the expense of the immune system and ultimately, host defense against infection (8). These changes include hypoglycemia, increases in immunosuppressive glucocorticoids, and reductions in circulating leptin (9–11). Associated with these alterations are defects in macrophage and neutrophil effector functions, decreases in serum complement, atrophy of the thymus and spleen, and reductions in circulating lymphocytes (8–10, 12).

Leptin is a pleiotropic hormone that has been identified as an important signal in the neuroendocrine response to fasting that regulates energy homeostasis and immune function (9–11, 13, 14). Under normal circumstances, blood leptin levels are positively correlated with total body fat mass, but decline dramatically during fasting disproportionately to body fat stores (15–17). We have previously reported that leptin-deficient mice exhibit an impaired host response against gram-negative pneumonia in vivo and this defect was associated with impaired macrophage and neutrophil phagocytosis of Klebsiella pneumoniae and reduced macrophage leukotriene synthesis in vitro (18, 19). All of these defects could be restored with exogenous leptin in vitro. In the current study, we asked if a physiologic stimulus to reduce circulating leptin levels (fasting for 48 h) impaired host defense against pneumococcal pneumonia. We also tested the effects of maintaining circulating leptin levels during acute energy deprivation on the host response against pneumococcal pneumonia in vivo. We observed that leptin reconstituted the fasting-induced host defense impairments against S. pneumoniae. This is the first report, to our knowledge, that demonstrates that leptin administration in vivo plays a protective role in pulmonary antibacterial host defense.

	METHODS

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Mice
C57BL/6j mice, 10 to 12 wk old, were obtained from Jackson Laboratories (Bar Harbor, ME) and maintained under specific pathogen-free conditions. All experiments were in compliance with the Animal Care and Use Committee of the University of Michigan.

Acute Starvation Model
Mice were randomly assigned to one of three groups: (1) ad libitum fed for 48 h (control) and given intraperitoneal injections of saline; (2) fasted for 48 h and given intraperitoneal injections of saline; or (3) fasted for 48 h and given recombinant murine leptin (Calbiochem, La Jolla, CA), 1 µg/g initial body weight, via intraperitoneal injections. Injections were given at 9:00 A.M. and 6:00 P.M. This leptin replacement protocol during fasting has been shown to achieve, 6 to 12 h postinjection, circulating leptin levels similar to those of ad libitum–fed animals (9, 11). All animals were provided with unlimited access to water.

S. pneumoniae Inoculation
S. pneumoniae serotype 3, 6303, was obtained from the American Type Culture Collection (Manassa, VA), and aliquots were grown to midlogarithmic phase in Todd-Hewett broth with 0.5% yeast extract (Difco, Detroit, MI) at 37°C. The concentration of bacteria was determined spectrophotometrically (A₆₀₀; see online supplement for details). Mice were anesthetized with ketamine and xylazine (80 and 10 mg/kg of body weight, respectively), and 10⁵ cfu of S. pneumoniae, suspended in 40 µl of saline, were administered via the intranasal route.

Bronchoalveolar Lavage and Peripheral Blood Cell Differential Counts
Bronchoalveolar lavage (BAL) was performed as previously described (20) and peripheral blood was obtained by orbital bleeding from uninfected mice and infected mice 24 h after S. pneumoniae challenge. The total number and differential counts of viable leukocytes in BAL fluid (BALF) and peripheral blood, isolated after red blood cell lysis (Unopette Microcollection System; Becton-Dickson, Rutherford, NJ), were determined as previously reported (18).

Determination of Lung and Blood S. pneumoniae Colony-forming Units
Twenty-four hours after S. pneumoniae challenge, lung homogenate and blood colony-forming units were determined as previously described (21).

Cytokine, Leptin, Corticosterone, and Glucose Determinations
Murine cytokines granulocyte-macrophage colony–stimulating factor (GM-CSF), interleukin 6 (IL-6), IL-10, IL-12, IFN-, macrophage inflammatory protein 2 (MIP-2), tumor necrosis factor (TNF-) (OPTEIA kits; BD Pharmingen, San Diego, CA), and leptin (Assay Designs, Ann Arbor, MI) were determined in BALF and lung homogenates after extraction as previously described (18). Leptin and corticosterone (Assay Designs) levels were also determined in blood samples by ELISA. Blood glucose was determined using a glucometer (Glucometer Elite; Bayer, Elkhart, IN).

Alveolar Macrophage Leukotriene B₄ Determination
Murine alveolar macrophages (AMs) were obtained by lavage, washed once in phosphate-buffered saline, resuspended in Roswell Park Memorial Institute (RPMI) 1640 (Invitrogen, Carlsbad, CA) to a concentration of 10⁵ cells/ml, and stimulated with the calcium ionophore A23187 for 30 min at 37°C in 5% CO₂ in air. The culture medium was assayed for leukotriene B₄ (LTB₄) using commercially available EIA kits (Cayman Chemical, Ann Arbor, MI).

AM Killing and Phagocytosis of S. pneumoniae In Vitro
For killing experiments, 1 x 10⁶ cfu of S. pneumoniae were cultured in RPMI 1640 and 10% autologous serum with or without 5 x 10⁵ AMs from mice of all treatment groups. Three samples from each tube were serially diluted and plated on soy-based blood agar plates (Difco) before (Time 0) and 90 min after incubation. After 16 h of incubation at 37°C, S. pneumoniae colony-forming units were enumerated. A total of 2 x 10⁵ AMs were incubated with 2 x 10⁶ cfu of fluorescently labeled (BODIPY FL; Molecular Probes, Eugene, OR) S. pneumoniae with 2.5% autologous serum in RPMI (total volume, 1 ml) for 30 min. The percentage of AMs that had phagocytosed fluorescent S. pneumoniae was determined by counting 200 macrophages in random fields using fluorescent microscopy (1,000x), and the data in experimental animals were expressed as a percentage of the values observed in AMs from fed animals (see online supplement for details).

Statistical Analysis
Where appropriate, mean values were compared using a paired t test, a one-way analysis of variance, or a Kruskal-Wallis test on ranks for nonparametric data. The Student-Newman-Keuls or the Dunnett's test was used for mean separation. In all cases, a p value of less than 0.05 was considered significant.

	RESULTS

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Effect of Fasting and S. pneumoniae Challenge on Body Weight and Leptin
To deplete circulating leptin levels, we used a 48-h fast before S. pneumoniae challenge. We also administered leptin to fasted mice to determine if this would preserve circulating leptin levels as indicated by previous reports (11, 14). As shown in Figure 1, 48 h of fasting resulted in a reduction of approximately 4 g or 18% of the initial body weight. Similar weight losses were observed in the fasted animals given leptin. By 72 h (24 h post–S. pneumoniae challenge), body weight had declined an additional 1.5 g in both the fasted and fasted animals given leptin. In the fed animals, we observed a decline of 1 g (5%) in body weight 24 h after S. pneumoniae challenge. As anticipated, blood leptin levels declined in uninfected animals after fasting. When exogenous leptin was given to fasted animals, blood leptin was maintained at levels similar to those observed in fed animals (Figure 2A). Blood leptin levels increased in all groups after S. pneumoniae challenge, were lowest in fasted animals, and were not different between fed and fasted mice given leptin. No differences in lung homogenate leptin levels were observed between treatment groups in uninfected animals. In contrast, lung homogenate leptin levels postinfection increased twofold in fed and 10-fold in fasted mice given leptin (Figure 2B).

View larger version (14K): [in this window] [in a new window]   Figure 1. Total body weights of mice that were fed ad libitum (solid diamonds), fasted for 48 h (open squares), or fasted for 48 h with exogenous leptin (solid circles) at baseline, 48 h, and 24 h after S. pneumoniae challenge. n = 5 mice/group. *p < 0.05 versus the fasted and fasted-plus-leptin groups.

View larger version (17K): [in this window] [in a new window]   Figure 2. Blood (A) and lung homogenate (B) leptin levels in mice fed ad libitum, fasted for 48 h, and fasted for 48 h with exogenous leptin at baseline (open bars) and 24 h after S. pneumoniae challenge (solid bars). n = 8–9 mice/group. *p < 0.05 versus fed and fasted-plus-leptin group; p < 0.05 versus respective baseline; #p < 0.05 versus fed and fasted mice.

View larger version (13K): [in this window] [in a new window]   Figure 3. Exogenous leptin maintains pulmonary bacterial clearance in fasted mice 24 h post–S. pneumoniae challenge. Lung S. pneumoniae colony-forming units (CFU) in mice fed ad libitum (solid bar), fasted for 48 h (open bar), and fasted for 48 h with exogenous leptin (gray bar; 1 µg/g initial bodyweight twice daily) 24 h after S. pneumoniae challenge. n = 4–5 mice/group. *p < 0.05 versus fed and fasted-plus-leptin groups.

View larger version (17K): [in this window] [in a new window]   Figure 4. Lung mononuclear/macrophage (Mono/Mac; open bars) and polymorphonuclear neutrophils (solid bars) 24 h after S. pneumoniae challenge in bronchoalveolar lavage fluid (BALF) obtained from mice ad libitum fed (control), fasted for 48 h, and fasted for 48 h with exogenous leptin. n = 4–5 mice/group. *p < 0.05 versus fed and fasted-plus-leptin groups.

View larger version (14K): [in this window] [in a new window]   Figure 5. Peripheral blood leukocyte counts obtained from mice fed ad libitum (control), fasted for 48 h, and fasted for 48 h with exogenous leptin at baseline (open bars) and 24 h after S. pneumoniae challenge (solid bars). n = 4–5 mice/group. *p < 0.05 versus fed and fasted-plus-leptin group; p < 0.05 versus respective baseline.

View larger version (13K): [in this window] [in a new window]   Figure 6. Maintenance of bronchoalveolar levels of interleukin-6 (IL-6; solid bars) and macrophage inflammatory protein 2 (MIP-2; hollow bars) 24 h post–S. pneumoniae challenge in fasted mice given leptin. BAL was performed 24 hafter S. pneumoniae challenge in mice fed ad libitum, fasted for 48 h, and fasted for 48 h with exogenous leptin. n = 4–5 mice/group. *p < 0.05 versus fed and fasted-plus-leptin groups.

View larger version (12K): [in this window] [in a new window]   Figure 7. Exogenous administration of leptin to fasted mice in vivo maintains stimulated LTB4 synthesis in AMs in vitro. AMs were obtained by lavage from mice fed ad libidum (control; solid bars), fasted for 48 h (open bars), and fasted for 48 h with exogenous leptin (gray bars). The cells were adjusted to a concentration of 105 cells/ml and cultured with A23187 for 30 min. LTB4 was assessed by a commercially available EIA kit. Bars represent the mean of 3–4 separate experiments ± SEM. *p < 0.05 versus control and fasted-plus-leptin groups.

View larger version (21K): [in this window] [in a new window]   Figure 8. Effect of exogenous leptin administration on alveolar macrophage (AM) phagocytosis and killing of S. pneumoniae. AMs were harvested from mice fed ad libitum (solid bars), fasted for 48 h (open bars), and fasted for 48 h with exogenous leptin (gray bars). For the AM killing experiments (A), S. pneumoniae was cultured in medium in the absence (without AMs; checkered bar) or presence of AMs. Samples were recovered from each culture before and after 90 min of culturing at 37°C. The data are presented as the percentage of initial bacteria surviving after 90 min of culture. Bars represent the mean of 3–4 separate experiments ± SEM performed in triplicate. *p < 0.05 versus control and fasted-plus-leptin groups. AM phagocytosis of fluorescent S. pneumoniae (B) is expressed relative to the value in fed animals; p < 0.05 versus fasted and fasted-plus-leptin groups.

	DISCUSSION

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Previously, we observed severe host-defense impairments against gram-negative pneumonia in genetically leptin-deficient mice. In the current study, we tested the effects of a physiologic reduction in leptin induced by acute starvation on pulmonary host defense. We also studied the effects of leptin administration to fasted animals to determine the role of leptin in fasting-induced immune suppression. After an intranasal challenge with S. pneumoniae, pulmonary bacterial clearance was impaired in fasted animals and this defect was associated with reduced PMN accumulation and IL-6 and MIP-2 levels in the BALF. In addition, peripheral blood leukocyte counts did not increase after S. pneumoniae challenge in fasted animals. We also observed that LTB₄ synthesis and phagocytosis and killing of S. pneumoniae in vitro were also impaired in AMs from fasted animals. Leptin administration to fasted mice restored bacterial clearance, circulating and BALF PMN counts, IL-6 and MIP-2 levels in BALF, and AM LTB₄ synthesis and bacterial killing. These results demonstrate that leptin deficiency plays an important role in the impaired host defense against pneumococcal pneumonia in energy deprivation, and suggests a potential role for this adipokine as a therapeutic agent in the energy-deprived immunocompromised host.

Increases in both blood and lung-homogenate leptin levels were observed in both fed and fasted animals after intranasal S. pneumoniae challenge. This observation was consistent with our previous report showing that leptin levels increase in the blood and lungs of mice challenged with K. pneumoniae via the intratracheal route (18). Others have also reported elevated leptin levels in the blood and tissues during inflammation and infection (25–29). Although cells other than adipocytes, such as T cells and macrophages, are capable of leptin synthesis (26, 30), the adipocytes located in various fat depots are probably the major source of leptin produced during bacterial pneumonia that can leak into the lung interstitium and alveolar space with other plasma proteins. The mechanism that would account for the observed increases of lung leptin to supranormal levels after S. pneumoniae challenge among the fasted animals given exogenous leptin is unclear. We speculate that it may reflect increased microvascular permeability in response to pulmonary inflammation, which resulted in preferential leptin accumulation in the lung. The presence of increased leptin levels in the lung may have directly enhanced bacterial clearance by augmenting AM cytokine and LTB₄ synthesis.

IL-6, LTB₄, and MIP-2 are known to play protective roles in the host response against bacterial pneumonia, and the reduction in the levels of these mediators produced in fasted animals was associated with an increase in lung S. pneumoniae burden and lower numbers of PMNs (31, 32). When IL-6 knockout mice were challenged with S. pneumoniae, their survival was reduced and their pulmonary bacterial clearance was defective (32). The mechanism responsible for these impairments is not clear. However, it is likely that IL-6 produces both pro- and antiinflammatory effects in the lung during pneumococcal pneumonia. High doses of IL-6 enhance PMN phagocytosis and superoxide release and increase the survival of PMNs by inhibiting apoptosis (33, 34). The antiinflammatory effects of IL-6 include the inhibition of the proinflammatory cytokines TNF- and IL-1 and the induction of an important tissue inhibitor of matrix metalloproteinase (TIMP-1). These effects may limit damage to pulmonary tissues during pneumococcal pneumonia and prevent extrapulmonary bacterial dissemination (35–37).

LTB₄ also plays an essential role in protecting the host against both Klebsiella and pneumococcal pneumonia (22, 31). LTB₄ is not only a potent chemoattractant of PMNs to sites of infection but it also augments the ability of AMs and PMNs to phagocytose and kill K. pneumoniae in vitro (20, 24, 38, 39). The PMN chemoattractant MIP-2 has also been shown to activate PMNs for improved phagocytosis and killing of Escherichia coli (40). The ability of exogenous leptin to improve bacterial clearance in fasted animals may have been due to the restoration of these mediators that are known to enhance leukocyte activation and PMN accumulation. Furthermore, leptin has been shown to augment the synthesis of IL-6, MIP-2, and LTB₄ (18, 41–43).

AMs from fasted mice exhibited a modest reduction in their ability to phagocytose S. pneumoniae in vitro and we have previously reported that phagocytosis of K. pneumoniae was attenuated in AMs and PMNs harvested from leptin-deficient mice. We have also shown that culturing these cells with leptin in vitro reconstitutes phagocytosis and that administering leptin to leptin-deficient mice in vivo restores the phagocytic defect in PMNs (18, 19). However, the provision of exogenous leptin to fasted mice did not affect AM phagocytosis of S. pneumoniae, suggesting that the impairment in bacterial clearance observed in fasted animals could not be explained by changes in AM phagocytosis. The reconstitution of pulmonary bacterial clearance in fasted animals given exogenous leptin was partially explained by the restoration of AM bactericidal function. Although the mechanism(s) by which leptin restored killing of S. pneumoniae in AMs from fasted mice is a subject for future investigation, we speculate that leptin may have augmented the elaboration of bactericidal reactive oxygen species because this effect has been observed in human PMNs treated with leptin in vitro (44).

The net accumulation of PMNs into the lungs during bacterial pneumonia reflects local lung determinants for recruitment and survival as well as the magnitude of production of these cells by the bone marrow. Therefore, the reduced number of PMNs found in the BALF of the fasted mice may be attributed to both a reduction in the elaboration of pulmonary MIP-2 and LTB₄, as well as the lower numbers of these cells found in peripheral blood samples. This latter defect cannot be explained by decreases in GM-CSF induced by fasting because we did not observe significant differences between treatment groups in the most abundant source of this cytokine during bacterial pneumonia (the lung homogenates) in infected animals (data not shown). The maintenance of peripheral blood PMNs observed in fasted animals given leptin post–S. pneumoniae challenge may have been due to the direct effects of leptin, which has been shown to stimulate the proliferation of murine myelocytic and hematopoietic progenitor cells in vitro (45). Another plausible explanation is that leptin may have promoted PMN survival as this adipokine has been shown to inhibit apoptosis in neutrophils and dendritic cells by inducing the expression of antiapoptotic proteins bcl-₂ and bcl-_XL (46, 47).

The ability of starvation to suppress immune responses and increase susceptibility to infectious disease has been recognized for a number of years (48). Physiologic adaptations to starvation include increases in glucocorticoids that ultimately act to maintain blood glucose levels by promoting gluconeogenesis through the metabolism of energy substrates from skeletal muscle and adipose tissue. Reductions in circulating lymphocytes and atrophy of lymphoid tissues also accompany acute starvation in mice (10, 14). Hypoglycemia is known to suppress the respiratory burst and, potentially, microbial killing in peripheral blood PMNs (49). Similarly, pharmacologic doses of glucocorticoids are known to decrease PMN recruitment and cytokine synthesis, and predispose the host to opportunistic infections (50, 51). We observed that acute starvation resulted in weight loss, hypoglycemia, elevations in blood corticosterone, and reduced serum leptin levels. While the provision of exogenous leptin did maintain circulating leptin levels at baseline and after S. pneumoniae challenge, it did not significantly affect blood glucose or corticosterone levels. These results indicate that the ability of leptin to reverse the fasting-induced suppression of the innate immune response against S. pneumoniae was not due to alterations in blood glucose or glucocorticoid levels.

In summary, we have demonstrated that sustaining circulating leptin levels during fasting can prevent impairments in pulmonary host defense against S. pneumoniae. This report provides novel insights into the role of leptin in the regulation of the innate immune response against bacterial infection in vivo and is the first study, to our knowledge, that demonstrates that leptin administration in vivo plays a protective role against bacterial pneumonia. These results support the hypothesis that leptin is a key link between nutritional status and innate immune function, and these findings provide a rationale for future studies exploring the role of leptin as a therapeutic agent to augment the immune response in the energy-deprived immune-suppressed host.

	Acknowledgments

 
The authors thank Dr. John Younger for helpful insight into the discussion of data.

	FOOTNOTES

 
Supported by grants from the American Lung Association (RG-056-N) and the University of Michigan Office of the Vice President of Research.

This article has an online supplement, which is accessible from this issue's table of contents at www.atsjournals.org

Originally Published in Press as DOI: 10.1164/rccm.200506-909OC on October 6, 2006

Conflict of Interest Statement: None of the authors have a financial relationship with a commercial entity that has an interest in the subject of this manuscript.

Received in original form June 13, 2005; accepted in final form October 3, 2005

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