Manipulation of innate immunity by bacterial pathogens

The past decade has witnessed tremendous growth in two related fields: innate immunity and microbial pathogenesis. Many pathogens have evolved mechanisms to infect their hosts in the face of a fully functional innate immune system, and there are numerous examples by which pathogens avoid recognition and/or suppress inflammation. In this review, I suggest that pathogens not only survive the innate immune response, but use it to promote their pathogenesis.     

Intrapulmonary expression of macrophage inflammatory protein 1alpha (CCL3) induces neutrophil and NK cell accumulation and stimulates innate immunity in murine bacterial pneumonia

Macrophage inflammatory protein 1alpha (MIP-1alpha) (CCL3) is an important mediator of leukocyte recruitment and activation in a variety of inflammatory states, including infection. A recombinant human type 5 adenovirus containing the murine MIP-1alpha cDNA (AdMIP-1alpha) was constructed to determine the effect of transient intrapulmonary expression of MIP-1alpha on leukocyte recruitment, activation, and bacterial clearance in a murine model of Klebsiella pneumoniae pneumonia. The intratracheal administration of AdMIP-1alpha resulted in both time- and dose-dependent expression of MIP-1alpha mRNA and protein within the lung. Importantly, the intrapulmonary overexpression of MIP-1alpha resulted in a maximal 35- and 100-fold reduction in lung and blood bacterial burden, respectively, in animals cochallenged with K. pneumoniae, which was associated with a significant increase in neutrophil and activated NK cell accumulation. Furthermore, the transgenic expression of MIP-1alpha during bacterial pneumonia resulted in enhanced expression of gamma interferon mRNA, compared to that observed in Klebsiella-challenged animals pretreated with control vector. These findings indicate an important role for MIP-1alpha in the recruitment and activation of selected leukocyte populations in vivo and identify this cytokine as a potential immunoadjuvant to be employed in the setting of localized bacterial infection.     

Opiate abuse, innate immunity, and bacterial infectious diseases

The first line of defense against invading bacteria is provided by the innate immune system. Morphine and other opiates can immediately disrupt the body’s first line of defense against harmful external bacteria. Opiate, for example morphine, abuse degrades physical and physiologic barriers, and modulates phagocytic cells (macrophages, neutrophils) and, nonspecific cytotoxic T cells (γδ T), natural killer cells, and dendritic cells, that are functionally important for carrying out a rapid immune reaction to invading pathogens. In vitro studies with innate immune cells from experimental animals and humans and in vivo studies with animal models have shown that opiate abuse impairs innate immunity and is responsible for increased susceptibility to bacterial infection. However, to better understand the complex interactions between opiates, innate immunity, and bacterial infection and develop novel approaches to treat and even prevent bacterial infection in the opiate-abuse population, there is an urgent need to fill the numerous gaps in our understanding of the cellular and molecular mechanisms by which opiate abuse increases susceptibility to bacterial infection. Received: 2008.05.23, Accepted: 2008.07.28     

Modulation of pulmonary innate immunity during bacterial infection: animal studies

Both the increasing number of immunocompromised patients susceptible to pneumonia and the development of bacterial resistance are significant problems related to the treatment of pneumonia. The primary outcome of treatment for pneumonia is to tip the balance towards a successful host response. An ideal approach would be a combination of immunomodulation and conventional antimicrobial therapy. It is of increasing importance to understand the components of innate immunity, before immunomodulatory therapy can be applied to patients. Much of our knowledge of the role of alveolar macrophages, cytokines and chemokines in the pathogenesis of pneumonia is derived from animal studies on experimental pneumonia. This article summarizes current information on the role of an alveolar macrophage (AM) and AM-derived mediators in host defense against pneumonia.     

Trained innate immunity

The innate immune system acts rapidly in an identical and nonspecific way every time the body is exposed to pathogens. As such, it cannot build and maintain immunological memory to help prevent reinfection. Researchers contend that trained immunity is influenced by intracellular metabolic pathways and epigenetic remodeling. The purpose of this review was to explore the topic of trained innate immunity based on the results of relevant previous studies. This systematic review entailed identifying articles related to trained innate immunity. The sources were obtained from PubMed using different search terms that included “trained innate immunity,” “trained immunity,” “trained,” “innate,” “immunity,” and “immune system.” Boolean operators were used to combine terms and phrases. A review of previous study results revealed that little is currently known about the molecular and cellular processes that mediate or induce a trained immune response in animals. However, it is believed that alterations in the phenotypes of cell populations and the numbers of specific cells may play a critical role in mediating the trained immune response. Increasing evidence shows that the protective processes and actions that occur during a secondary infection are not entirely linked to the adaptive immune system. Instead, these events also involve heightened activation of innate immune cells. While trained innate immune cells may have a shorter memory, they assist in the fight against pathogens and provide cross-protection. Identification of the mechanisms and molecules that underlie trained innate immunity has highlighted important features of the human immune response. Such advances continue to open doors for future research on how the body responds to disease-causing pathogens.

     

Regulation of mast cell-mediated innate immunity during early response to bacterial infection

Summary Although the area of research on the role of MCs in innate immunity is relatively new, a number of studies that are reviewed here provide substantial evidence that MCs play a critical role in host immune defense against gram-negative bacteria. The studies show that mast cells have the ability to recognize and engulf bacteria and they release a number of inflammatory mediators including interleukin (IL)-4, IL-6, IL-10, TNFα, and leukotrienes in response to bacterial challenge. MC-derived TNFα and leukotrienes are shown to be important for bacterial clearance and early recruitment of phagocytic help at the site of infection. Studies directed at elucidating the molecular mechanisms associated with mast cell recognition of bacteria and subsequent events leading to mast cell mediator release revealed that GPI anchored CD48 molecule present on the cell surface of mast cells serves as a receptor for the bacterial adhesion molecule, FimH. The ligation of CD48 receptor by FimH-expresing bacteria results in bacterial uptake into caveolar chambers. This distinct mechanism of bacterial uptake promot es bacteral survival inside the cytosol of the mast cells. Although the exact mechanism(s) of how MC-dependent inflammatory responses are regulated is currently not known, recent studies have shown that complement, CD11β/CD18 (Mac-1) and protein tyrosine kinase JAK3, and TLR4 are important for the full expression of MC-dependent innate immunity in mice.     

Homeostatic inflammation in innate immunity

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Mast cells in innate immunity

Summary: Mast cells are known to be the main effector cells in the elicitation of the IgE-mediated allergic response. The specific location of mast cells within tissues that interface the external environment, and the extent of their functional capacity, including the ability to phagocytose and to produce and secrete a wide spectrum of mediators, have led investigators to propose a potential role for mast cells in innate immune responses. Certain microorganisms have been found to interact either directly or indirectly with mast cells. This interaction results in mast cell activation and mediator release which elicit an inflammatory response or direct killing leading to bacterial clearance. The in vivo relevance of these in vitro observations has been demonstrated by the use of complement-deficient and/or mast cell-deficient and mast cell-reconstituted mice. It thus has been shown that both C3 and mast cell- and tumor necrosis factor‐a-dependent recruitment of circulating leukocytes with bactericidal properties are crucial to a full response in certain models of acute infection. Modulation of mast cell numbers in vivo was also found to affect the host response against bacterial infection. Thus, mast cells do have a role in innate immunity in defined animal models of bacterial infection. Whether mast cells participate in innate immune responses in the protection of the human host against bacteria remains to be determined.     

Iron-withholding strategy in innate immunity

The knowledge of how organisms fight infections has largely been built upon the ability of host innate immune molecules to recognize microbial determinants. Although of overwhelming importance, pathogen recognition is but only one of the facets of innate immunity. A primitive yet effective antimicrobial mechanism which operates by depriving microbial organisms of their nutrients has been brought into the forefront of innate immunity once again. Such a tactic is commonly referred to as the iron-withholding strategy of innate immunity. In this review, we introduce various vertebrate iron-binding proteins and their invertebrate homologues, so as to impress upon readers an obscured arm of innate immune defense. An excellent comprehension of the mechanics of innate immunity paves the way for the possibility that novel antimicrobial therapeutics may emerge one day to overcome the prevalent antibiotic resistance in bacteria.     

Mast cells in innate immunity

Mast cells have been most extensively studied in their traditional role as an early effector cell of allergic disease. However, in the majority of individuals, it might be the role of this cell as a sentinel in host defense that is most important. Mast cells have been repeatedly demonstrated to play a critical role in defense against bacterial infections, and evidence for their involvement in early responses to viral and fungal pathogens is growing. Mast cells are activated during innate immune responses by multiple mechanisms, including well-established responses to complement components. In addition, novel mechanisms have emerged as a result of the explosion of knowledge in our understanding of pattern-recognition receptors. The mast cell shares many features with other innate immune effector cells, such as neutrophils and macrophages. However, a unique role for mast cells is defined not only by their extensive mediator profile but also by their ability to interact with the vasculature, to expedite selective cell recruitment, and to set the stage for an appropriate acquired response.     

NK cells in innate immunity

NK cells have an important role in innate immune responses, particularly in anti-viral immunity. Recent studies have revealed a molecular basis for NK cell recognition of virus-infected cells, implicating the activating KIR and Ly49 receptors and NKG2D in this process. Additionally, mutual cooperation between NK cells and dendritic cells suggests that these innate cells can shape the nature of an adaptive immune response. These findings, as well as advances in understanding NK cell development and homeostasis, indicate that NK cell biology is more sophisticated than previously appreciated.     

Differentially imprinted innate immunity by mucosal boost vaccination determines antituberculosis immune protective outcomes,independent of T-cell immunity

Homologous and heterologous parenteral prime–mucosal boost immunizations have shown great promise in combating mucosal infections such as tuberculosis and AIDS. However, their immune mechanisms remain poorly defined. In particular, it is still unclear whether T-cell and innate immunity may be independently affected by these immunization modalities and how it impacts immune protective outcome. Using two virus-based tuberculosis vaccines (adenovirus (Ad) and vesicular stomatitis virus (VSV) vectors), we found that while both homologous (Ad/Ad) and heterologous (Ad/VSV) respiratory mucosal boost immunizations elicited similar T-cell responses in the lung, they led to drastically different immune protective outcomes. Compared with Ad-based boosting, VSV-based boosting resulted in poorly enhanced protection against tuberculosis. Such inferior protection was associated with differentially imprinted innate phagocytes, particularly the CD11c⁺CD11b^+/− cells, in the lung. We identified heightened type 1 interferon (IFN) responses to be the triggering mechanism. Thus, increased IFN-β severely blunted interleukin-12 responses in infected phagocytes, which in turn impaired their nitric oxide production and antimycobacterial activities. Our study reveals that vaccine vectors may differentially imprint innate cells at the mucosal site of immunization, which can impact immune-protective outcome, independent of T-cell immunity, and it is of importance to determine both T-cell and innate cell immunity in vaccine studies.     

Toll-like receptors in innate immunity

Functional characterization of Toll-like receptors (TLRs) has established that innate immunity is a skillful system that detects invasion of microbial pathogens. Recognition of microbial components by TLRs initiates signal transduction pathways, which triggers expression of genes. These gene products control innate immune responses and further instruct development of antigen-specific acquired immunity. TLR signaling pathways are finely regulated by TIR domain-containing adaptors, such as MyD88, TIRAP/Mal, TRIF and TRAM. Differential utilization of these TIR domain-containing adaptors provides specificity of individual TLR-mediated signaling pathways. Several mechanisms have been elucidated that negatively control TLR signaling pathways, and thereby prevent overactivation of innate immunity leading to fatal immune disorders. The involvement of TLR-mediated pathways in autoimmune and inflammatory diseases has been proposed. Thus, TLR-mediated activation of innate immunity controls not only host defense against pathogens but also immune disorders.     

Chemokines and innate immunity

Our environment contains a great variety of infectious microbes that may be potentially destructive and threaten our survival. As soon as microbes try to establish a site of infection, the host launches a complex defense system. Innate immunity is a non-specific response and serves as the first-line of defense where phagocytes, such as neutrophils and macrophages, and NK cells play central roles in neutralizing and clearing microorganisms. Thus, migration of cells into infectious foci and subsequent activation of these cells appear to be a critical step, enabling the host to achieve effective and efficient removal of microbes. Over the past decade, chemokines have been identified as chemotactic cytokines that attract and activate specific types of leukocyte populations in vitro. There is now evidence that the magnitude of chemokines' expression in infectious diseases is strongly associated with the severity of the inflammatory responses. Blocking chemokines or their receptors with neutralizing antibodies or gene targeting technology has allowed us to understand the pathological significance of chemokines in animal models of infectious diseases. Growing evidence suggests that chemokines play an important beneficial role in immune system development, homeostasis and in innate immunity, which may pave the way for new therapeutic strategies for the treatment of infectious diseases.     

Understanding how leading bacterial pathogens subvert innate immunity to reveal novel therapeutic targets

Staphylococcus aureus (SA) and group A Streptococcus (GAS) are prominent Gram-positive bacterial pathogens, each associated with a variety of mucosal and invasive human infections. SA and GAS systemic disease reflects diverse abilities of these pathogens to resist clearance by the multifaceted defenses of the human innate immune system. Here we review how SA and GAS avoid the bactericidal activities of cationic antimicrobial peptides, delay phagocyte recruitment, escape neutrophil extracellular traps, inhibit complement and antibody opsonization functions, impair phagocytotic uptake, resist oxidative burst killing, and promote phagocyte lysis or apoptosis. Understanding the molecular basis of SA and GAS innate immune resistance reveals novel therapeutic targets for treatment or prevention of invasive human infections. These future therapies envision alternatives to direct microbial killing, such as blocking disease progression by neutralizing specific virulence factors or boosting key innate immune defenses.     

蚯蚓与固有免疫

动物的免疫系统包括固有免疫和适应性免疫.固有免疫是指动物机体与生具有的抵御微生物或者外来异物侵袭的能力,包括组织屏障作用、细胞免疫作用和体液免疫作用.固有免疫细胞识别病原体表面的模式分子而活化,经特殊信号转导途径产生免疫效应.蚯蚓属无脊椎动物,其免疫系统缺乏免疫球蛋白,适应性免疫不发达,主要依赖固有免疫机制来抵御微生物的感染.     

Aging and innate immunity

Adaptive immunity undergoes severe deterioration with age and represents the main problem in the elderly. However, evidence accumulated over the last decade supports the hypothesis that aging also has a profound impact on innate immunity, which in turn markedly impacts the health and longevity of older people.