Özet

In vivo Imaging Method to Distinguish Acute and Chronic Inflammation

Published: August 16, 2013
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Özet

We describe a non-invasive imaging method for distinguishing inflammatory stages. Systemic delivery of luminol reveals areas of acute inflammation dependent upon MPO activity in neutrophils. In contrast, injection of lucigenin allows for visualization of chronic inflammation dependent upon Phox activity in macrophages.

Abstract

Inflammation is a fundamental aspect of many human diseases. In this video report, we demonstrate non-invasive bioluminescence imaging techniques that distinguish acute and chronic inflammation in mouse models. With tissue damage or pathogen invasion, neutrophils are the first line of defense, playing a major role in mediating the acute inflammatory response. As the inflammatory reaction progresses, circulating monocytes gradually migrate into the site of injury and differentiate into mature macrophages, which mediate chronic inflammation and promote tissue repair by removing tissue debris and producing anti-inflammatory cytokines. Intraperitoneal injection of luminol (5-amino-2,3-dihydro-1,4-phthalazinedione, sodium salt) enables detection of acute inflammation largely mediated by tissue-infiltrating neutrophils. Luminol specifically reacts with the superoxide generated within the phagosomes of neutrophils since bioluminescence results from a myeloperoxidase (MPO) mediated reaction. Lucigenin (bis-N-methylacridinium nitrate) also reacts with superoxide in order to generate bioluminescence. However, lucigenin bioluminescence is independent of MPO and it solely relies on phagocyte NADPH oxidase (Phox) in macrophages during chronic inflammation. Together, luminol and lucigenin allow non-invasive visualization and longitudinal assessment of different phagocyte populations across both acute and chronic inflammatory phases. Given the important role of inflammation in a variety of human diseases, we believe this non-invasive imaging method can help investigate the differential roles of neutrophils and macrophages in a variety of pathological conditions.

Introduction

Inflammation is a highly regulated biological response involved in a variety of human diseases, including microbial infection 1, wound healing 2, diabetes 3, cancer 4, cardiovascular 5, neurodegenerative 6, and autoimmune diseases 7. Tissue inflammation requires proper coordination of various immune cells in order to achieve pathogen clearance, tissue repair, and disease resolution. Neutrophils and macrophages are key immune mediators of tissue inflammation. In the acute phase of inflammation, neutrophils are the first responders to various harmful stimuli and tissue damage 8. The neutrophils rapidly extravasate from circulation to the site of injury, where the cells inactivate invading microbes by releasing anti-microbial granules and phagocytosis. During phagocytosis, neutrophils engulf invading microbes into phagosomes, within which the cells produce high levels of superoxide (O2·). Phagosomal superoxide is the primary source of many downstream reactive oxygen species (ROS). For example, superoxide can be dismutated to hydrogen peroxide (H2O2) by spontaneous dismutation or by superoxide dismutase (SOD) 9, 10. In neutrophils, myeloperoxidase (MPO) further converts hydrogen peroxide to anti-microbial hypochlorous acid (HOCl) 11. As the inflammatory responses continue, circulating monocytes gradually migrate into the site of injury and differentiate into mature macrophages 2, whose phagocytic function help remove inactivated pathogens and cell debris. In addition, as a key regulator in the later phase of inflammation, macrophage promotes tissue repair by producing anti-inflammatory cytokines 12 and by generating extracellular ROS at a lower level 9. The ROS generated at this later stage regulate tissue remodeling, new vessel formation, and reepithelialization 13.

Phagocyte NADPH oxidase (Phox) is the primary source of superoxide production in both neutrophils and macrophages 9. Phox is a multi-subunit complex whose assembly is tightly regulated 9. The holoenzyme contains several cytosolic regulatory subunits (p67phox, p47phox, p40phox, and RAC) and a membrane-bound heterodimer cytochrome b558 (consist of subunit CYBA and CYBB). Cytochrome b558 is the reaction core within which the CYBB subunit (also known as p91phox and NOX2) carries out the primary redox chain reaction 9. Interestingly, its assembly sites are different between neutrophils and macrophages. In resting neutrophils, cytochrome b558 is mostly present in the membrane of intracellular storage granules 14. During phagocytosis, neutrophils assemble the holoenzymes at phagosomes 9, where high levels of MPO activity are also present. The neutrophil Phox rapidly consumes oxygen and exerts its microbicidal power by ROS production, a phenomenon termed the respiratory burst 11. In contrast, macrophages have a lower level of MPO expression and cytochrome b558 is mostly found in the plasma membrane 15, 16. Thus neutrophils produce high levels of superoxide for anti-microbial activity, while macrophages generate less superoxide for regulatory functions 15.

Since inflammation is an intricate in vivo process, non-invasive imaging methods specific for different phases of inflammation would allow quantitative and longitudinal assessment of disease models. Using mechanistic studies, we have previously demonstrated the use of two chemiluminescent agents, luminol (5-amino-2,3-dihydro-1,4-phthalazinedione) and lucigenin (bis-N-methylacridinium nitrate), for non-invasive imaging of acute and late (chronic) stages of inflammation, respectively 17. Luminol enables visualization of neutrophil MPO activity in the acute phase of inflammation 18-20, whereas lucigenin bioluminescence can be used to assess macrophage activity in association with the late phase or chronic inflammation 17. In this manuscript, we used two experimental inflammation models (s.c. PMA and s.c. LPS) to demonstrate these imaging techniques.

Protocol

Note: All animal studies were performed under approved institutional protocols and animal care guidelines.

1. Reagents and Solutions

  1. PMA solution for s.c. inoculation: Prepare a stock solution of phorbol 12-myristate 13-acetate (PMA) at 5 mg/ml in DMSO. Store the stock solution at -20 °C. Before inoculation, thaw the stock solution and dilute to 1 mg/ml PMA in PBS.
  2. LPS solution for s.c. inoculation: Dissolve lipopolysaccharide (LPS from Salmonella enterica serotype enteritidis) in sterile PBS at 1 mg/ml prior to s.c. inoculation.
  3. Luminol solution for acute phase imaging: Dissolve luminol (5-amino-2,3-dihydro-1,4-phthalazinedione, sodium salt) in sterile normal saline (0.9% NaCl) at 10 mg/ml. The solution can be stored at -20 °C before use.
  4. Lucigenin solution for chronic phase imaging: Dissolve lucigenin (bis-N-methylacridinium nitrate) in sterile normal saline at 2.5 mg/ml. The solution can be stored at -20 °C before use.

2. Subcutaneous PMA Inflammation Model

  1. Anesthetize NCr nude mice in an induction chamber with 1-2% isoflurane. Confirm general anesthesia by loss of movement and a constant respiratory rate. Transfer an animal to a nose cone supplied with isoflurane-mixed gas and keep the animal under anesthesia.
  2. Use an isopropyl alcohol wipe to clean and disinfect the injection site on the left flank.
  3. Using sterile technique, inject 50 μl of the PMA inoculation solution (containing 50 μg of PMA) into the subcutaneous space on the left flank. Remove excess fluid from the injection site by using an isopropyl alcohol pad. Avoid the use of analgesia as it may affect inflammatory responses.
  4. Move the animal back to the housing cage and closely monitor its recovery from anesthesia. In order to assist in the recovery, use a heating pad to keep the animal warm.

3. Subcutaneous LPS Inflammation Model

  1. Anesthetize C57BL/6J mice with 1-2% isoflurane in an induction chamber. Once establishing general anesthesia, transfer an animal to a nose cone supplied with isoflurane gas and keep the animal under anesthesia.
  2. Use an isopropyl alcohol wipe to clean the injection site on the left footpad.
  3. Using sterile technique, inject 50 μl of the LPS inoculation solution (containing 50 μg of LPS) into the left footpad. Remove excess fluid from the injection site by using an isopropyl alcohol pad. Avoid the use of analgesia as it may affect inflammatory responses.
  4. Move the animal back to the housing cage and closely monitor its recovery from anesthesia. Use a heating pad to keep the animal warm during recovery.

4. Bioluminescence Imaging of Inflammation

  1. Anesthetize the animal in an induction chamber with 1-2% isoflurane-mixed gas. Confirm general anesthesia by loss of movement and a constant respiratory rate.
  2. While the animal is still under anesthesia, intraperitoneally (i.p.) inject the luminol solution (10 mg/ml), or the lucigenin solution (2.5 mg/ml) for acute or chronic inflammation imaging, respectively. The final dosage is 100 mg/kg for luminol and 25 mg/kg for lucigenin. A lower dose of lucigenin (10-15 mg/kg) can be used to avoid possible toxicity for some mouse strains. Signs of toxicity include shortness of breath and respiratory distress. The C57BL/6J strain has lower lucigenin tolerability than the NCr nude strain.
  3. Transfer the animal into the imaging chamber of a bioluminescence imaging system.
  4. Perform sequential bioluminescence imaging at 1 min intervals. Each imaging step is comprised of 1 min acquisition time, f/stop = 1, binning = 16 and 0 sec delay.
  5. Within the image acquisition panel, to enable sequential multi-step imaging, click on the sequence setting button. Provide sufficient imaging steps in the acquisition profile to determine maximal luminescence output (usually 15 one-minute steps will suffice). The 15-min imaging section allows sufficient time for substrate absorption and systemic circulation.
  6. Remove the animal from the imaging chamber and move it back to the housing cage. In order to assist in the recovery, use a heating pad to keep the animal warm.
  7. During post-acquisition analysis, use the imaging software package to calculate peak total bioluminescent signal through standardized regions of interest (ROI). The images are present as radiance in photons/sec/cm2/sr with minimal and maximal threshold indicated. Quantitative data are presented as total flux in photons per second per ROI.

Representative Results

We performed longitudinal bioluminescence imaging to assess acute and chronic inflammation in experimental inflammation models. Phorbol 12-myristate 13-acetate (PMA) is a potent protein kinase C (PKC) agonist that activates Phox for superoxide anion production and triggers intense acute inflammatory responses 21. S.C. injection of 50 mg of PMA in NCr nude mice caused rapid skin irritation and acute inflammation at injection sites 18, 22, 23. We performed daily imaging for 4 days with the first images obtained as early as 3 hr after PMA injection. Figure 1 demonstrated the longitudinal bioluminescence imaging using luminol and lucigenin as substrates. At early stages of inflammation (3 hr), we observed significant luminol bioluminescence indicating high levels of neutrophil MPO activity at the sites of PMA injection. No significant lucigenin bioluminescence was observed during these early stages of inflammation. Starting on day 2, we observed scab formation and therefore reduced luminescence intensity. As wound healing became apparent (Figure 1A, day 3 and 4), we observed steady increase in lucigenin bioluminescence (Figure 1B). These results illustrate that luminol bioluminescence is associated with the acute phase of inflammation, whereas lucigenin bioluminescence is closely associated with tissue repair in the late phases of inflammation.

Independently, we s.c. injected 50 μg of lipopolysaccharide (LPS) in the footpads of wild-type C57BL/6J mice, and performed longitudinal bioluminescence imaging for up to 10 days (Figure 2A). LPS is a membrane component of Gram-negative bacteria. S.C. inoculation of LPS is capable of triggering strong inflammatory responses by TLR4 receptor activation and subsequent inflammatory chemokine/cytokine production 24. Unlike PMA which directly activates Phox for superoxide production, LPS requires a longer period of time to fully activate tissue infiltrating phagocytes 18. As neutrophils are the early responders to microbe infection, we observed elevated luminol bioluminescence during the first 4 days of acute inflammation, which declined after day 5 (Figure 2B). In contrast, lucigenin bioluminescence gradually increased in the late and chronic phase of inflammation (Figure 2B, days 5-10).

Together, these results demonstrate the ability to use differential substrate specificity to distinguish acute and chronic inflammatory stages. Importantly, imaging is mediated by the endogenous enzymatic activities of the immune cells, and there is no need for ectopic expression of reporters.

Figure 1
Figure 1. In vivo longitudinal bioluminescence imaging of acute and late phases of inflammation. (A) We induced local tissue inflammation by s.c. injection of 50 μg PMA, and performed daily luminol (100 mg/kg, i.p.) and lucigenin (25 mg/kg, i.p.) bioluminescence imaging starting at 3 hr after PMA injection. No significant background auto-luminescence was observed at sites of inflammation without chemiluminescent agents. (B) Quantitative representation of luminol and lucigenin bioluminescence at injection sites. In the acute phase of inflammation, luminol signals dominated the bioluminescence output (3 hr). In the later stages of inflammation, the sites of injection had higher lucigenin bioluminescence compared with luminol (day 4). Error bars represent the standard deviations of bioluminescence measurements at each imaging time point. Click here to view larger figure.

Figure 2
Figure 2. (A) 50 μg of LPS was injected s.c. into the footpads of C57BL/6J mice. Longitudinal bioluminescence imaging with luminol and lucigenin were performed daily for 10 days. (B) Quantitative representation of luminol and lucigenin bioluminescence at LPS injection sites. Luminol bioluminescence increased during the first 4 days of acute inflammation. However, in the late/chronic phases of inflammation, luminol signals rapidly declined and lucigenin bioluminescence gradually increased. Error bars represent the standard deviations of bioluminescence measurements at each imaging time point. Click here to view larger figure.

Discussion

In this report, we demonstrate a bioluminescence method for non-invasive imaging of inflammation in living animals. Taking advantage of two luminescent substrates, luminol and lucigenin, the method can distinguish different phases of inflammation. Luminol bioluminescence is associated with neutrophils in the acute phase of inflammation, whereas lucigenin bioluminescence is mediated by macrophages in the chronic phase. Relatively small (M.W. = 177.16 g/mol) and electrically uncharged, luminol can readily penetrate both plasma and phagosomal membrane 25-29. In addition, luminol luminescence is specific to the intracellular MPO activity in neutrophils 9. On the other hand, lucigenin is mostly membrane impermeable due to its larger size (M.W. = 510.5 g/mol) and two positive charges 25, 27-30.

Neutrophils and macrophages assemble the Phox holoenzyme at different subcellular locations. Although both reagents depend upon Phox to provide superoxide anion (O2·), the disparity in cell permeability and MPO-dependency enables the substrates to differentiate inflammatory phagocytes in disease models. Neutrophils express most of the Phox in the membrane of intracellular vesicles (phagosomes) 14, where high levels of MPO are also present. As a result, luminol bioluminescence is specifically associated with activated neutrophils during acute inflammation. In contrast, macrophages assemble Phox in the plasma membrane as they infiltrate and mature during chronic inflammation 15. Non-permeable lucigenin can directly interact with the extracellular superoxide generated by macrophages to produce chronic inflammatory bioluminescence.

Inflammation is a complicated in vivo process that requires proper coordination of many cell types and various extracellular signaling molecules. In this video report, we demonstrate the synergistic use of both luminol and lucigenin, to monitor acute and late (chronic) phase inflammation in animal models. Since these substrates are commercially available and relatively inexpensive, we believe this relatively simple and robust imaging method can be readily translated to in vivo applications in many disease areas. Of note, compared with PET, MRI and near-infrared (NIR) fluorescent imaging techniques, the chemiluminescent method is not ideal for deep tissue imaging due to the substrates’ blue emission spectra. To improve tissue penetration, it has been recently demonstrated that the blue chemiluminescence emission can be transferred to co-administrated nanoparticles for NIR emission 31. Further modification of their chemical structures could potentially enhance their quantum efficiency for stronger light output and refine their emission spectra for deeper tissue penetration.

Açıklamalar

The authors have nothing to disclose.

Acknowledgements

This work was supported by the Nancy Lurie Marks Foundation. We thank Dr. Nancy E. Kohl for critical reading of the manuscript. We thank Kin K. Wong for his assistance in preparing this video report.

Materials

Name of Reagent/Material Company Catalog Number Yorumlar
Phorbol 12-myristate 13-acetate (PMA) Sigma-Aldrich Co., St. Louis, MO P8139  
Lipopolysaccharide from Salmonella enterica serotype enteritidis Sigma-Aldrich Co., St. Louis, MO L2012  
Luminol (5-amino-2,3-dihydro-1,4-phthalazinedione, sodium salt) Sigma-Aldrich Co., St. Louis, MO A4685  
Lucigenin (bis-N-methylacridinium nitrate) Sigma-Aldrich Co., St. Louis, MO M8010  
IVIS Spectrum imaging system with Living Imaging 4.2 software package Caliper LS/Perkin Elmer, Hopkinton, MA    

Referanslar

  1. Premack, B. A., Schall, T. J. Chemokine receptors: gateways to inflammation and infection. Nat. Med. 2, 1174-1178 (1996).
  2. Singer, A. J., Clark, R. A. Cutaneous wound healing. N. Engl. J. Med. 341, 738-746 (1999).
  3. Wellen, K. E., Hotamisligil, G. S. Inflammation, stress, and diabetes. J. Clin. Invest. 115, 1111-1119 (2005).
  4. Weitzman, S. A., Gordon, L. I. Inflammation and cancer: role of phagocyte-generated oxidants in carcinogenesis. Blood. 76, 655-663 (1990).
  5. Ridker, P. M., Cushman, M., et al. Inflammation, aspirin, and the risk of cardiovascular disease in apparently healthy men. N. Engl. J. Med. 336, 973-979 (1997).
  6. Wyss-Coray, T., Mucke, L. Inflammation in neurodegenerative disease–a double-edged sword. Neuron. 35, 419-432 (2002).
  7. Hamilton, J. A. Colony-stimulating factors in inflammation and autoimmunity. Nat. Rev. Immunol. 8, 533-544 (2008).
  8. Harlan, J. M. Leukocyte-endothelial interactions. Blood. 65, 513-525 (1985).
  9. Bedard, K., Krause, K. H. The NOX family of ROS-generating NADPH oxidases: physiology and pathophysiology. Physiol. Rev. 87, 245-313 (2007).
  10. Rest, R. F., Spitznagel, J. K. Subcellular distribution of superoxide dismutases in human neutrophils. Influence of myeloperoxidase on the measurement of superoxide dismutase activity. Biochem. J. 166, 145-153 (1977).
  11. Hampton, M. B., Kettle, A. J., et al. Inside the neutrophil phagosome: oxidants, myeloperoxidase, and bacterial killing. Blood. 92, 3007-3017 (1998).
  12. Serhan, C. N., Savill, J. Resolution of inflammation: the beginning programs the end. Nat. Immunol. 6, 1191-1197 (2005).
  13. Jiang, F., Zhang, Y., et al. NADPH oxidase-mediated redox signaling: roles in cellular stress response, stress tolerance, and tissue repair. Pharmacol. Rev. 63, 218-242 (2011).
  14. Calafat, J., Kuijpers, T. W., et al. Evidence for small intracellular vesicles in human blood phagocytes containing cytochrome b558 and the adhesion molecule CD11b/CD18. Blood. 81, 3122-3129 (1993).
  15. Johansson, A., Jesaitis, A. J., et al. Different subcellular localization of cytochrome b and the dormant NADPH-oxidase in neutrophils and macrophages: effect on the production of reactive oxygen species during phagocytosis. Cell. Immunol. 161, 61-71 (1995).
  16. Kumar, A. P., Piedrafita, F. J., et al. Peroxisome proliferator-activated receptor gamma ligands regulate myeloperoxidase expression in macrophages by an estrogen-dependent mechanism involving the -463GA promoter polymorphism. J. Biol. Chem. 279, 8300-8315 (2004).
  17. Tseng, J. C., Kung, A. L. In vivo imaging of inflammatory phagocytes. Chem Biol. 19, 1199-1209 (2012).
  18. Gross, S., Gammon, S. T., et al. Bioluminescence imaging of myeloperoxidase activity in vivo. Nat. Med. 15, 455-461 (2009).
  19. Kielland, A., Blom, T., et al. In vivo imaging of reactive oxygen and nitrogen species in inflammation using the luminescent probe L-012. Free Radic. Biol. Med. 47, 760-766 (2009).
  20. Zhou, J., Tsai, Y. T., et al. Noninvasive assessment of localized inflammatory responses. Free Radic. Biol. Med. 52, 218-226 (2012).
  21. Karlsson, A., Nixon, J. B., et al. Phorbol myristate acetate induces neutrophil NADPH-oxidase activity by two separate signal transduction pathways: dependent or independent of phosphatidylinositol 3-kinase. J. Leukoc. Biol. 67, 396-404 (2000).
  22. Taylor, R. G., McCall, C. E., et al. Histopathologic features of phorbol myristate acetate-induced lung injury. Lab Invest. 52, 61-70 (1985).
  23. Fukaya, S., Matsui, Y., et al. Overexpression of TNF-alpha-converting enzyme in fibroblasts augments dermal fibrosis after inflammation. Lab Invest. 93, 72-80 (2013).
  24. Lu, Y. C., Yeh, W. C., et al. LPS/TLR4 signal transduction pathway. Cytokine. 42, 145-151 (2008).
  25. Aitken, R. J., Buckingham, D. W., et al. Reactive oxygen species and human spermatozoa: analysis of the cellular mechanisms involved in luminol- and lucigenin-dependent chemiluminescence. J. Cell. Physiol. 151, 466-477 (1992).
  26. Allen, R. C., Loose, L. D. Phagocytic activation of a luminol-dependent chemiluminescence in rabbit alveolar and peritoneal macrophages. Biochem. Biophys. Res. Commun. 69, 245-252 (1976).
  27. Caldefie-Chezet, F., Walrand, S., et al. Is the neutrophil reactive oxygen species production measured by luminol and lucigenin chemiluminescence intra or extracellular? Comparison with DCFH-DA flow cytometry and cytochrome c reduction. Clin. Chim. Acta. 319, 9-17 (2002).
  28. Dahlgren, C., Aniansson, H., et al. Pattern of formylmethionyl-leucyl-phenylalanine-induced luminol- and lucigenin-dependent chemiluminescence in human neutrophils. Infect. Immun. 47, 326-328 (1985).
  29. Dahlgren, C., Karlsson, A. Respiratory burst in human neutrophils. J. Immunol. Methods. 232, 3-14 (1999).
  30. Aerts, C., Wallaert, B., et al. Release of superoxide anion by alveolar macrophages in pulmonary sarcoidosis. Ann. N.Y. Acad. Sci. 465, 193-200 (1986).
  31. Zhang, N., Francis, K. P., et al. Enhanced detection of myeloperoxidase activity in deep tissues through luminescent excitation of near-infrared nanoparticles. Nat Med. , (2013).

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Bu Makaleden Alıntı Yapın
Tseng, J., Kung, A. L. In vivo Imaging Method to Distinguish Acute and Chronic Inflammation. J. Vis. Exp. (78), e50690, doi:10.3791/50690 (2013).

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