Molecular half-full mechanisms by phagocityc cells on invasive Aspergilosis Mecanismos moleculares mediados por células fagocíticas en la aspergilosis invasiva Karla Rossanet Dzul-Rosado,MSc1,
Viridiana Martínez-Campos, QFB22, 1Profesor Investigador Titular, Centro de Investigaciones Regionales Dr. Hideyo Noguchi, Universidad Autónoma de Yucatán, Mérida, México. e-mail: karla.dzul@uady.mx Received for publication May 6, 2011, Accepted for publication November 11, 2011 Summary Fungus from the Aspergillus genus mainly affects lung tissue, occurring when the integrity of the host immune system is compromised. The human body uses immunocompetence conditions from mechanical and enzymatic defenses and the action of the innate immune system cells and also uses adaptive responses to control infection. Neutrophils, macrophages, and dendritic cells are critical as antifungal effector cells possess surface receptors that recognize fungal structures and trigger specific responses. TLRs and Dectin-1 the most studied for this interaction. TLRs are responsible for the production and release of cytokines and Dectin-1 is essential in the phagocytosis of the particle recognition and production of ROS. The best-studied cytokines and its crucial role in the response to Aspergillus spp. are TNF-α, IFN-γ, and IL-12.In this work, we reviewed the main mechanisms related to molecular receptors on phagocytic cells involved in the recognition of Aspergillus spp. Understanding the immune response in situations of immunocompetence and its comparison in immunodeficient organisms could provide alternatives to control invasive aspergillosis. Keywords: Aspergillus; Immune system; Toll-like receptors; Dectin-1; DC-SIGN; MR and cytokines. Resumen Los hongos del género Aspergillus afectan sobre todo al tejido pulmonar, presentándose cuando la integridad del sistema inmune del hospedero se ve comprometida. El organismo en condiciones de inmunocompetencia se vale para controlar la infección tanto de defensas mecánicas, enzimas y la acción de células del sistema inmune innato y respuestas adaptativas. Los neutrófilos, macrófagos y células dendríticas son de fundamental importancia como células efectoras antifúngicas, poseen receptores de superficie como TLR, Dectina-1, DC-SIGN y receptor de manosa (MR) que reconocen estructuras micóticas y desencadenan respuestas específicas. TLR y Dectina-1, son los más estudiados para esta interacción. Los TLR son los responsables de la producción y liberación de citocinas y Dectina-1 es fundamental en la fagocitosis de la partícula reconocida y la producción de ROS. DC-SIGN es el receptor esencial para el reconocimiento de las esporas de Aspergillus spp. por células dendríticas y macrófagos, y se encuentra presente en células pulmonares con actividad fagocítica. El MR reconoce estructuras micóticas después de la internalización del hongo y promueve la liberación de una amplia variedad de citocinas. Las citocinas mejor estudiadas y cuyo papel es crucial en la respuesta contra Aspergillus spp. son TNF-α, IFN-γ e IL-12.En el presente trabajo, se revisaron los principales mecanismos moleculares relacionados con los receptores presentes en las células fagocíticas implicadas en el reconocimiento de Aspergillus spp. La comprensión de la respues ta inmune en situaciones de inmunocompetencia y su comparación en organismos inmunodeficientes podría proporcionar alternativas que permitan el control de la aspergilosis invasiva. Palabras clave: Aspergillus; Sistema inmune; Receptores Toll-like; Dectina-1; DC-SIGN; MR y citocinas. The medical advances in the 1990s have led to greater longevity of the population, as well as to a greater number of patients with some type of organ transplant, chemotherapy as a means of combating neoplasia, or an increase in patients on immunosuppressive regimens, which also increased the number of patients with different degrees of immunosuppression. This condition has led to the development of opportunistic infections, particularly those caused by fungi, which cannot be limited to local infection, but also get to spread to a systemic infection, such as invasive aspergillosis (IA)1.
Gaspar Peniche-Lara, MSc3, Jorge E. Zavala-Castro, PhD1*
2Assistant research, Centro de Investigaciones Regionales Dr. Hideyo Noguchi, Universidad Autónoma de Yucatán, Mérida, México. e-mail: chavymtz@hotmail.com
3Profesor Investigador Asociado, Unidad Interinstitucional de Investigación Clínica y Epidemiológica, Facultad de Medicina, Universidad Autónoma de Yucatán, Mérida, México. e-mail: gaspar.peniche@uady.mx
1*Profesor Investigador Titular, Centro de Investigaciones Regionales Dr. Hideyo Noguchi, Universidad Autónoma de Yucatán, Mérida, México. e-mail: zcastro@uady.mx
Immune defense against invasive aspergillosis (IA)
The main route of infection is inhalation of spores in the air, followed by deposition in the bronchioles or alveolar spaces5,6. The spores are inhaled, trapped in mucus, and then actively transported by the motion of the cilia to the oropharynx, where they are ingested or expelled through expectoration6.
Mechanical defenses, including the cough reflex and sneezing help expel particles inhaled7. Cells in the respiratory tract produce large numbers of molecules with antimicrobial activity, some of which have antifungal activity against A. fumigatus. Such is the case of lactoferrin produced by neutrophils and epithelial cells that bind iron and deprive the fungi of this element, which is essential for growth8.
Several enzymes play an important role as a defense against Aspergillus species. Elastase and cathepsin G are two serine proteases present in the azurophilic granules of neutrophils that have activity against Aspergillus9. Chitinases are produced by macrophages and epithelial cells are capable of degrading chitin, which is an essential component of A. fumigatus10.
Neutrophils, macrophages and dendritic cells are critical as antifungal effector cells. In healthy subjects, spores not eliminated by mucociliary depuration are recognized by the alveolar macrophages from epitelium, which try to eliminate the spores or the damage they produce.Additional effector cells are recruited to infection sites of infection by the action of inflammatory signals such as cytokines, chemokines and complement components11. Macrophages phagocyte spores and they can only destroy spores that are distended12. The spores that escape the death of macrophages and germinate become the target of neutrophils, which are capable of destroying the hyphaer5.
Dendritic cells (DC) initiate innate and adaptive immune response of a wide range of microorganisms13. These cells capture and process antigens, express co-stimulatory molecules, migrate to lymphoid organs, and secrete cytokines that initiate immune responses and these T cells provide the appropriate signals14,15. The differentiation of CD4 + T cells into T-helper cell (Th) type 1 (Th1) or type 2 (Th2) and the development of pathway-specific responses is a key determinant of susceptibility or resistance to invasive fungal infections. The predominance of Th1 responses on Th2-type correlate with protection against fungal infections16,17. The defense against invasion by A. fumigatus is impaired by the action of inflammatory cytokines (IL-4 and IL-10), whose depletion improves the elimination of spores18,19. High levels of IL-10 increase survival of the spores because they affect the respiratory burst in macrophages20. The proinflammatory cytokines IFN-γ and TNF-α, IL-12, IL-1, and IL-6 play a protective role against the AI20 and are essential for optimal activation of phagocytosis at infection sites21. TNF-α and INF-γ are critical components of innate immunity in both immunocompetent patients and those with some degree of immunosuppression. When macrophages are in contact with structures of A. fumigatus they mainly produce these cytokines, which are essential for recruitment of neutrophils in the lungs and also play an important role in epithelial cell response against AI22-26. The role of IL-12 in Th1 cell growth is linked to its ability to promote the production of INF-γ and encourage expansion and survival of cells producing this cytokine. The production of IL-12 is linked to the response of alveolar macrophages from viable spores of A. fumigatus, dependent on TLR27. High levels of IL-10 affect the production of INF-γ and have been detected in patients with aspergillosis and are associated to susceptibility of infection. However, this cytokine secretion by Treg cells could be a consequence rather than the cause of the infection27.
Likewise, other cells such as Th17 lymphocytes and Th regulators play an important role in infection with A. fumigatus. Th17 lymphocytes, a type of lymphocyte recently discovered characterized by the release of IL-17, are believed to be important in the immune response against pathogenic microorganisms including bacteria and fungi, as well as contributing to the development of autoimmune diseases28. Th17 responses have been implicated in immunity against fungi, suggesting that this type of response is required for the protection of C. albicans28,29. Dectin-1 is involved in the generation of the protective responseof IL-17 on Aspergillus fumigatus pulmonary infection30. Just as there is also evidence that DC-SIGN receptors, TLR2, and mannose receptor are involved in the production and modulation of Th17 responses28,31,32. The inflammation present in these clinical pictures is controlled by expansion, activation and recruitment of regulatory Th cells, which can suppress neutrophil activity. Regulation is an essential component in the host response in infection and allergy to the fungus, but could be inhibited by it. Also, germination of conidia interferes with anti-inflammatory responses and activity of T lymphocytes regulators33.Phagocytosis in invasive aspergillosis
Polymorphonuclear neutrophils (PMN) are the predominant immune cells in the acute phase of most fungal infections in different clinical situations and are essential for the eradication of pathogens34. The role of PMN in the innate immune system is the destruction of microorganisms, which is carried out through oxidative and non-oxidative mechanisms35.
Oxidative mechanisms involve ROS generation through the NADPH oxidase pathway, which produces superoxide and also through the MPO, which catalyzes the conversion of hydrogen peroxide and superoxide to hypochlorous acid and hydroxyl radicals. The neutrophil granules contain cationic peptides, which are part of the non-oxidative mechanisms of microbial killing directly, plus they produce a wide variety of cytokines and chemokines35.
The phagocytes produce TNF-α in response todifferent morphological structures of Aspergillus, but production of IL-12 is linked to the internalization of the spores; whereas, IL-4 and IL-10 is produced only by phagocytosis hyphae of the fungus36.Cell wall composition of Aspergillus spp.
The cell wall of Aspergillus spp. is comprised mainly of polysaccharides, which are divided into two groups depending on their solubility in alkaline solutions. The alkali-insoluble fraction, believed responsible for the rigidity of the cell wall is composed of linear β-glucans and β(1.3)/(1.4)-glucans, which had not been described in any other fungus, as well as GM, chitin, and β(1,3)-glucans (BG) as major components37,38. The BG are involved in pathogenassociated molecular pattern (PAMP) recognition of Aspergillus spp., stimulate and prolong PMN adherence, as well as stimulate the respiratory burst by these cells39.
The innate immune system does not respond to the inactive or resting spores of Aspergillus and responses occur only when the spores are in the process of germination22,23,40,41 because the remodeling and expansion of the cell wall spores during germination results in the exposure of β-glucans present in fungi41.Receptors
The main receptor involved in recognizing BG in Aspergillus in myeloid cells is the receptor called Dectin-142. There is evidence that TLRs and MR are involved in the production of inflammatory responses against Aspergillus infection. Like TLRs that initiate these responses23,43, DC-SING also plays an important role in the AI to be essential for the initiation of the adaptive response.
Toll-like receptors (TLR)
In PMN, TLRs are activated by different mechanisms and play an important role in controlling the functions of phagocytic cells in fungal infection. TLRs involved in host defense against A. fumigatus are TLR2, TLR4, and TLR9, which recognize zymozano, mannans, and fungal DNA. Clearly, the role of TLR2 and TLR4 in recognizing Aspergillus and structures in triggering responses that cause the release of proinflammatory cytokines27,40.
CD14, TLR2, TLR4, and the adapter protein MyD88 play an important role in immune responses of mouse peritoneal macrophages and human monocytes, against different growth phases of A.fumigatus44. Signaling by TLR2 to produce TNF-á is predominantly on TLR4 in the development of a response against Aspergillus infection44,45. TLR2 plays a greater role than TLR4 in the phagocytosis of A. fumigatus46. The response from TLR4 is effective against germ spores of this fungus, but does not have the ability to recognize hyphae; unlike TLR2, which does not decrease cytokine production in response to different growth phases of Aspergillus in macrophages45. In the absence of TLR2 and MyD88 inflammatory cytokine production is not triggered; however, TLR2 and MyD88 are not required for phagocytosis and ROS production in response to zymosan, given that in the absence of these molecules there is still release of ROS and phagocytosis of these particles, suggesting mechanisms independent of TLR2 and MyD88 in the production of ROS and mediated phagocytosis43.Dectin-1
Dectin-1 is a highly expressed receptor in various populations of myeloid cells, particularly monocytes, macrophages, neutrophils, and dendritic cells also found in a population of T cells in which expression is low, additionally, it is expressed in the B48 lymphocyte.
Dectin-1 receptors are the predominant PRR in the recognition of a wide variety of ligands β-1, 3 and β-1, 6 glucan of fungi and plants22,49,50, which have been implicated in the recognition and phagocytosis of different yeasts and filamentous fungi by using a βdependent recognition glucans present in the cell wall of these microorganisms51.The Dectin-1 receptor is required for defense against Aspergillus; the first evidence of the in vivo role of Dectin-1 receptors in the recognition of A. fumigatus was reported in a study that assessed the production of proinflammatory cytokines after co-culture of alveolar macrophages with A. fumigatus alive and competitive carbohydrate monoclonal antibodies or receptor blocking Dectin-122.
The results were the reduction of inflammatory responses, especially the production of proinflammatory cytokines: TNF-α, IL-1α, IL-1β, IL6, macrophage inflammatory protein 2 (MIP2), macrophage inflammatory protein 1α (MIP-1α), GCSF and GM-CSF, and decreased recruitment of neutrophils22,30.These receptors are important in alveolar macrophages in the induction of Th1-type responses for host defense against optimal Aspergillus infection. Th1 lymphocytes, when stimulated with Aspergillus, produce IFN-γ23. It has been established that β-glucan recognition by Aspergillus receptor Dectin-1 is an important cofactor triggering inflammatory responses via TLR2.In macrophages, the cooperative role of Dectin-1 and TLR2 is required for TNF-α production in response to the recognition of fungal structures, and the first demonstration of interaction between TLR and other PRR23.
Although Dectin-1 results in increased inflammatory responses produced by the recognition of TLR2 in macrophages and dendritic cells mediated by this recognition, the receiver is not capable of producing these responses alone. The dectin-1 receptor can form phagosomes; this activity increases in the presence of TLR2.Alveolar macrophages lacking the expression of any of these receptors are more susceptible to infection by A. fumigatus, and the production of IL-1, TNF-α, and MIP-1 is decreased resulting in an insufficient recruitment of neutrophils in the lung and uncontrolled fungal growth30. This is because the collaboration of these receptors occurs by parallel activation of Syk pathways and TLR/MyD88 Dectin-1, resulting in the substantial degradation of IkB. Deficiency of any of these proteins involves the abolition of collaborative responses to the production of TNF-α, MIP-1, and MIP-242.
Recent studies indicate that the cooperative role of TLR and Dectin-1 is not restricted to TLR2, but that there is also collaboration from TLR4, TLR5, TLR7, and TLR952.
DC-SING (Dendritic cell-specific ICAM-3grabbing nonintegrin)
DC-SING is a Type-II lecithin that functions as adhesion receptor. This receiver has the ability to interact with A. fumigatus spores, which like anti-DCSIGN are capable of inhibiting the binding of spores to dendritic cells. The clinical relevance of this interaction is emphasized by the presence of a DCSIGN receptor on lung dendritic cells and alveolar macrophages53.
The binding and internalization of A. fumigatus spores in dendritic cells is mediated by DC-SIGN through recognition of cell wall polysaccharides like the fungus. This receptor plays a critical role in the capture of A. fumigatus spores by dendritic cells, which is strengthened by its detection in alveolar macrophages and further suggests that this participation is done in the initial AI state53.Mannose receptor (MR)
The MR is a receptor for endocytosis, which has a wide range of endogenous ligands such as antigens and microbial antigens, allowing participation in a wide variety of cellular processes including pathogen recognition and cell migration. Although this receptor induces a variety of cellular responses, the molecular mechanisms responsible for intracellular signal transduction are not clear. The recognition of fungi by this receptor could occur only after internalization of the fungus and promotes the production of cytokines such as TNF-α, GM-CSF, IL-12, IL-8, IL-6, and IL-1β28,54.
The MR stimulation with Candida spp. is capable of inducing significant levels of IL-17, with Dectin1 and TLR2 able to amplify these responses28,32. The structure recognition of A. fumigatus by the Dectin-1 receptor causes increased shedding of the mannose receptor54.Internalization
Phagocytosis of A. fumigatus spores by alveolar macrophages depends primarily on the degree of polymerization of actin at the site of contact between the spore and the macrophage. IP-3K, an indispensable element for the phagocytosis of these spores, can be carried out. It also requires phagolysosome acidifi-cation to eliminate spores ingested by the action of several ATPases, which accumulate in the phagosomal membrane during phagolysosome maturation55.
Respiratory burst
Phagocytes respond to different stimuli through a phenomenon known as respiratory burst, which depends on nicotinamide adenine dinucleotide phosphate (NADPH) oxidase. After activation of macrophages and neutrophils, the cytosolic components of the NADPH oxidase system are translocated to join the membrane components; the enzyme complex catalyzes the production of superoxide anion because it accepts electrons from cytosolic NADPH and donates it to molecular oxygen found in the phagocytic vacuole; thereby, producing ROS. The activation of this enzyme complex is regulated by the influx of calcium released from cellular deposits through phosphorylation of PKC56.
ROS are essential for the elimination of A. fumigatus in alveolar macrophages and neutrophils12,35. The lack of a functioning NADPH oxidase system in optimal conditions allows the internalization of the spores of this organism, but lacks the capacity to eliminate them. It is further noted that the administration of corticosteroids prevents the eradication of Aspergillus spores by altering the mechanisms of ROS production12. The mechanism of ROS release is dependent on Syk in macrophages57; however, it requires only partial recognition of structures by receptor Dectin-1 in macrophages and neutrophils58. In contrast to the NADPH oxidase, inducible nitric oxide synthase (iNOS)12 and the MPO59 do not play an important role in the elimination of A. fumigatus.
Conclusion
Opportunistic mycoses like AI are affections that produce severe clinical damages in immunocompromised patients in whom the prognosis is unfavorable. Currently, there is information about the mechanisms of the immune system to deal with these infections.
In the innate immune system, responses to AI phagocytic cells, macrophages, neutrophils, and dendritic cells are predominantly involved, and these are the link between innate and adaptive immunity. Phagocytic cells have mechanisms activated in response to contact with Aspergillus. MR, DC-SIGN, TLR2, and Dectin-1 receptors are essential in the recognition of Aspergillus structures on the cell surface of phagocytes.Dectin-1 is required for the internalization of fungus and production of ROS; it is necessary to control Aspergillus structures in the body. TLR2 triggers the production of proinflammatory cytokines. These cytokines promote the eradication of infection through cell recruitment to the infection site and activation of adaptive responses. Although the role of Dectin-1 and TLR2 is essential in the response to the AI, other receptors such as DC-SIGN and MR play an important role in all of these receptors being critical to the resolution of the infection. The fundamental problem in patients with AI is that the immune system is compromised and the body's own response is poor; however, because phagocytic cells are the first contact of the fungus with the host; these cells constitute an attractive research area.
Understanding their roles and mechanisms could be key to provide empowering strategies to modulate the response of the host phagocytes and allow resolving the infection.
Conflict of interest. No potential conflict of interest exists in this manuscript. If any, these will be declared in this document and/or explained in the title page, identifying funding sources.
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