Home   About Us   eMedicine Search   Drug Development   Feedback   Google Scholar Search   Intranet 
Literature Database   News   Photo Gallery   Publications   Site Map   Site Search   Useful Links 
 

 Back to Literature Database
 

Enhanced by Neuroinformation

Toll-like Receptors Reviews

(73 References)

Akira, S. and S. Sato (2003). "Toll-like receptors and their signaling mechanisms." Scand J Infect Dis 35(9): 555-62.

            Toll-like receptors (TLRs) play a crucial role in the recognition of invading pathogens and the activation of subsequent immune responses against them. Individual TLRs recognize distinct pathogen-associated molecular patterns (PAMPs). The TLR family harbors an extracellular leucine-rich repeat (LRR) domain as well as a cytoplasmic domain that is homologous to that of interleukin-1 receptor (IL-1R). Upon stimulation, TLR recruits IL-1R-associated protein kinases via adaptor MyD88, and finally induces activation of nuclear factor-kappaB and mitogen-activated protein kinases. However, the response to TLR ligands varies, indicating the diversity of TLR signaling pathways. Besides MyD88, several novel adaptor molecules have recently been identified. Differential utilization of these adaptor molecules may provide the specificity in the TLR signaling. Characterization of each TLR signaling pathway will reveal the molecular mechanism of self-tolerance as well as cross-tolerance in response to a variety of PAMPs.

Akira, S. (2003). "Toll-like receptor signaling." J Biol Chem 278(40): 38105-8.

Akira, S. and H. Hemmi (2003). "Recognition of pathogen-associated molecular patterns by TLR family." Immunol Lett 85(2): 85-95.

            Toll-like receptors (TLRs) are type I transmembrane proteins involved in innate immunity by recognizing microbial conserved structures. Recent studies have shown that TLR3 recognizes dsRNA, a viral product, whereas TLR9 recognizes unmethylated CpG motifs frequently found in the genome of bacteria and viruses, but not vertebrates. TLR7 recognizes small synthetic immune modifiers including imiquimod, R-848, loxoribine, and bropirimine, all of which are already applied or promising for clinical use against viral infections and cancers. Plasmacytoid dendritic cells express TLR7 and TLR9, and respond to TLR7 and TLR9 ligands by producing a large amount of interferon (IFN-alpha). These results indicate that TLR3, TLR7 and TLR9 may play an important role in detecting and combating viral infections.

Backhed, F. and M. Hornef (2003). "Toll-like receptor 4-mediated signaling by epithelial surfaces: necessity or threat?" Microbes Infect 5(11): 951-9.

            Recent data suggest that the lipopolysaccharide receptor Toll-like receptor (TLR) 4 is expressed by epithelial cells and might play a role in the mucosal host defense against Gram-negative bacteria. However, since many body surfaces are colonized by the physiological microflora, activation of epithelial TLRs must be tightly controlled to avoid unintended stimulation and mucosal inflammation. The present review summarizes the current understanding of TLR4-mediated recognition and addresses specific questions on microbial recognition on mucosal surfaces, with particular emphasis on the gastrointestinal and urinary tract.

Bell, J. K., G. E. Mullen, et al. (2003). "Leucine-rich repeats and pathogen recognition in Toll-like receptors." Trends Immunol 24(10): 528-33.

            Toll-like receptors (TLRs) are the major cell-surface initiators of inflammatory responses to pathogens. They bind a wide variety of pathogenic substances through their ectodomains (ECDs). Here, we ask: what is the structural basis for this interaction? Toll-like receptor ECDs comprise 19-25 tandem copies of a motif known as the leucine-rich repeat (LRR). No X-ray structure of a TLR-ECD is currently available but there are several high-resolution LRR-containing proteins that can be used to model TLRs. We suggest that the basic framework of TLRs is a horseshoe-shaped solenoid that contains an extensive beta-sheet on its concave surface, and numerous ligand-binding insertions. Together, these insertions and the beta-sheet could provide a binding surface that is 10-fold greater in area than binding surfaces in antibodies and T-cell receptors.

Berche, P. (2003). "[Bacterial aggression]." Ann Pharm Fr 61(4): 270-5.

            In all living species, the first line of defence against microbial aggressions is constituted by innate immunity. During Evolution, it appears in invertebrates and plants, long before adaptive immunity, which appears in vertebrate. Adaptive immunity induces acquired resistance against microorganisms through random somatic rearrangements of genes encoding immunoglobulins and T cell receptors, thus generating a high level of diversity of receptors (>10(9)) in response to microbial aggressions. Acquired resistance is not vertically transmitted and reflects the "infectious history" of every individual. In contrast, innate immunity relies on recognition of antigens by a small number of weakly specific receptors (>10(2)) designated Pattern-Recognition Receptors (PRR) and is vertically transmitted by germinal cells. The PRR are expressed on macrophages dendritic cells and B lymphocytes and recognize antigenic structures highly conserved in the living world, termed Pathogen-Associated Molecular Patterns (PAMP), as lipopolysaccharides peptidoglycanes and lipoteichoic acids. PRR are secreted (complement, lectins), or expressed at the cell surface of cells to induce endocytosis or signaling (Toll-like receptors or TLRs). The recognition of antigens induces an immediate inflammatory response and triggers adaptive immunity. Among secreted PRR, the system of complement plays a major role in the immediate inflammatory response, controlling infections by its major role in opsonization, chemotactism and activation of leucocytes. TLRs induce the inflammatory response against microorganisms through NF-kB, a cytoplasmic factor controlling transcription of many genes, including cytokines (TNF, INF, IL-1, IL-2, IL-8, IL-12.) and defensines. So, within few minutes following microbial aggression, the inflammatory response is rapidly triggered to destroy infectious agents and to generate a long-term memory against pathogens.

Beutler, B., K. Hoebe, et al. (2003). "Lps2 and signal transduction in sepsis: at the intersection of host responses to bacteria and viruses." Scand J Infect Dis 35(9): 563-7.

            A phenotype-driven approach led to the first understanding of precisely what the Toll-like receptors (TLR) did, when it was determined that the mammalian endotoxin (lipopolysaccharide; LPS) receptor is encoded by TLR4. The TLRs are the primary sensors of the innate immune system, and without them, small inocula of microorganisms pose a major threat to the host, growing unchecked for a long period before they are recognized. Mutations that affect innate immune sensing may account for a substantial fraction of sepsis, and a highly significant excess of mutations in TLR4 has been identified in patients with systemic meningococcal disease. As such, it is important to understand the pathways that are responsible for innate immune sensing, including the signaling intermediates utilized by the TLRs. Random germline mutagenesis identified a locus, Lps2, which is required for normal responses to double-stranded RNA and LPS. Hence, a single transducer was found to serve both the TLR3 and TLR4 response pathways. The Lps2 mutation was found to ablate entirely the MyD88-independent pathway for LPS sensing, indicating that two and only two branches of the LPS sensing pathway exist in macrophages, and homozygotes for the mutation were resistant to LPS, but markedly susceptible to infection with mouse cytomegalovirus. Remarkably, Lps2 mutant mice entirely failed to produce type I interferons in response to a viral infection. It would appear that Lps2 is the most proximal component of a signal integration system required for innate immune responses to both viral and bacterial diseases. Positional cloning revealed that the TIR adapter protein Trif/Ticam-1 is structurally altered by the Lps2 mutation. This adapter is responsible for shared effects of responses to viral and bacterial pathogens.

Beutler, B., K. Hoebe, et al. (2003). "How we detect microbes and respond to them: the Toll-like receptors and their transducers." J Leukoc Biol 74(4): 479-85.

            Macrophages and dendritic cells are in the front line of host defense. When they sense host invasion, they produce cytokines that alert other innate immune cells and also abet the development of an adaptive immune response. Although lipolysaccharide (LPS), peptidoglycan, unmethylated DNA, and other microbial products were long known to be the primary targets of innate immune recognition, there was puzzlement as to how each molecule triggered a response. It is now known that the Toll-like receptors (TLRs) are the principal signaling molecules through which mammals sense infection. Each TLR recognizes a restricted subset of molecules produced by microbes, and in some circumstances, only a single type of molecule is sensed (e.g., only LPS is sensed by TLR4). TLRs direct the activation of immune cells near to and far from the site of infection, mobilizing the comparatively vast immune resources of the host to confine and defeat an invasive organism before it has become widespread. The biochemical details of TLR signaling have been analyzed through forward and reverse genetic methods, and full elucidation of the molecular interactions that transpire within the first minutes following contact between host and pathogen will soon be at hand.

Beutler, B. (2003). "Science review: key inflammatory and stress pathways in critical illness - the central role of the Toll-like receptors." Crit Care 7(1): 39-46.

            A pure reductionist approach can sometimes be used to solve an exceptionally complicated biologic problem, and sepsis is nothing if not complicated. A serious infection promptly leads to changes in many aspects of host physiology, including alterations in circulation, metabolism, renal, hepatic, and neuroendocrine function; all of these changes happen at once, and each influences one another. It is difficult to tease apart a problem of this sort, if only because the systems affected are so profoundly interactive. The key to understanding sepsis, insofar as we do understand it at present, was found in the use of genetic tools to study the very earliest events that take place at the interface of the pathogen and the host. The continued application of both forward and reverse genetic methods, in both mammals and insects, is steadily revealing the central biochemical events that occur during infection.

Beutler, B. and E. T. Rietschel (2003). "Innate immune sensing and its roots: the story of endotoxin." Nat Rev Immunol 3(2): 169-76.

            How does the host sense pathogens? Our present concepts grew directly from longstanding efforts to understand infectious disease: how microbes harm the host, what molecules are sensed and, ultimately, the nature of the receptors that the host uses. The discovery of the host sensors--the Toll-like receptors--was rooted in chemical, biological and genetic analyses that centred on a bacterial poison, termed endotoxin.

Beutler, B. (2003). "Innate immune responses to microbial poisons: discovery and function of the Toll-like receptors." Annu Rev Pharmacol Toxicol 43: 609-28.

            There are many circumstances under which a toxin exploits an endogenous receptor or another protein of host origin to work its untoward effects. In most instances, the receptor normally fulfills a function that has nothing to do with the toxin per se; that is, the toxin is not the "natural" ligand. The situation with endotoxin, however, is a remarkable one. The endotoxin receptor evolved to detect endotoxin. Why have mammals maintained a gene that can undermine their survival? The search for the endotoxin receptor answered this question and also revealed the essential function and biological strategy of the Toll-like receptors: principal sensors of the innate immune system.

Buentke, E. and A. Scheynius (2003). "Dendritic cells and fungi." Apmis 111(7-8): 789-96.

            Fungi comprise a group of microorganisms that in the past 20 years has become increasingly important as a cause of human disease. Few fungi are professional but instead opportunistic pathogens, and some fungi can even act as allergens. Dendritic antigen-presenting cells function as a link between innate and adaptive immunity and are therefore important in recognition of pathogens. Effective defense requires the host to discriminate between different pathogens to induce an appropriate response. Signaling from different groups of microbes can be mediated via the Toll-like receptors (TLRs), leading to activation of conserved host defense signaling pathways that control the expression of a variety of immune response genes. Different dendritic cells (DCs) express different patterns of recognition molecules, which indicate that they are more or less efficient when responding to certain pathogens. DCs have an important role in the induction of cell-mediated immune responses to fungi, and the studies reviewed here show that fungi, or possibly fungi-derived factors, provide a powerful activation stimulus to DCs, resulting in DC maturation with upregulation of co-stimulatory molecules and production of cytokine patterns leading to different T cell responses. The possibility of using ex vivo-generated DCs as therapeutic tools for restoring anti-fungal immunity is a challenge for the future.

Calandra, T. (2003). "Macrophage migration inhibitory factor and host innate immune responses to microbes." Scand J Infect Dis 35(9): 573-6.

            Among innate immune cells, macrophages play an essential role in the sensing and elimination of invasive microorganisms. Binding of microbial products to pathogen-recognition receptors stimulates macrophages to release cytokines and other effector molecules that orchestrate the host innate and adaptive immune responses. Recently, the protein known as macrophage migration inhibitory factor (MIF) has emerged as a pivotal mediator of innate immunity. First identified as a T-cell cytokine, MIF was rediscovered as a protein released by pituitary cells after exposure to endotoxin [lipopolysaccharide (LPS)] or bacteria and in response to stress. Monocytes, macrophages and lymphocytes constitutively express MIF, which is rapidly released after stimulation with bacterial endotoxins and exotoxins, and cytokines. MIF induces powerful proinflammatory biological responses and has been shown to be an important effector molecule of septic shock. High levels of MIF have been detected in the circulation of patients with severe sepsis and septic shock. Inhibition of MIF activity with neutralizing anti-MIF antibodies or deletion of the Mif gene led to a marked reduction in cytokine production and protected mice from lethal bacterial sepsis and toxic shock induced by Gram-negative endotoxin or Gram-positive exotoxins. Investigations into the mechanisms whereby MIF modulates innate immune responses to endotoxin and Gram-negative bacteria have shown that MIF up-regulates the expression of Toll-like receptor 4 (TLR4), the signal-transducing molecule of the LPS receptor complex. Thus, MIF enables cells, such as the macrophage, that are at the forefront of the host antimicrobial defences, to sense promptly the presence of invading Gram-negative bacteria and mount an innate immune response. Given that it is a pivotal regulator of innate immune responses to bacterial infections, MIF appears to be a perfect target for novel therapeutic interventions in patients with severe sepsis.

Dabbagh, K. and D. B. Lewis (2003). "Toll-like receptors and T-helper-1/T-helper-2 responses." Curr Opin Infect Dis 16(3): 199-204.

            PURPOSE OF REVIEW: Toll-like receptors (TLRs) are a family of pattern recognition receptors that are activated by specific components of microbes and certain host molecules. They constitute the first line of defense against many pathogens and play a crucial role in the function of the innate immune system. Recently, TLRs were observed to influence the development of adaptive immune responses, presumably by activating antigen-presenting cells. This has important implications for our understanding of how the host tailors its immune response as a function of specific pathogen recognition. The present review discusses the recent studies that demonstrate the role of TLRs in the regulation of adaptive T-helper-1 (Th1) and Th2 responses, and the mechanisms by which the effects are carried out. RECENT FINDINGS: Most studies have focused on the role of TLRs and components of their signaling pathways in the control of Th1-type immune responses, and on the implications for their use as antimicrobial agents, such as adjuvants in vaccines, or to treat or prevent the Th2-type dominated immune responses seen in allergies. TLR-deficient mice have been described and used to come to these conclusions. Although controversial, there is also evidence that TLRs may be important for Th2-type responses, possibly by augmenting the overall maturity of dendritic cells. SUMMARY: A greater understanding of the processes by which TLRs regulate adaptive immunity may yield not only improved ways to treat infectious diseases but also new approaches to the treatment and prevention of allergic and certain autoimmune disorders.

Dantzer, R. and E. E. Wollman (2003). "[Relationships between the brain and the immune system]." J Soc Biol 197(2): 81-8.

            The concept that the brain can modulate activity the immune system stems from the theory of stress. Recent advances in the study of the inter-relationships between the central nervous system and the immune system have demonstrated a vast network of communication pathways between the two systems. Lymphoid organs are innervated by branches of the autonomic nervous system. Accessory immune cells and lymphocytes have membrane receptors for most neurotransmitters and neuropeptides. These receptors are functional, and their activation leads to changes in immune functions, including cell proliferation, chimiotactism and specific immune responses. Brain lesions and stressors can induce a number of changes in the functioning of the immune system. All these changes are not necessarily mediated by the neuroendocrine system. They can also be dependent on autonomic nerve function. The communication pathways that link the brain to the immune system are normally activated by signals from the immune system, and they serve to regulate immune responses. These signals originate from accessory immune cells such as monocytes and macrophages and they are represented mainly by proinflammatory cytokines. Proinflammatory cytokines produced at the periphery act on the brain via two major pathways: (1) a humoral pathway allowing pathogen specific molecular patterns to act on Toll-like receptors in those brain areas that are devoid of a functional blood-brain barrier, the so-called circumventricular areas; (2) a neural pathway, represented by the afferent nerves that innervate the bodily site of infection and injury. In both cases, peripherally produced cytokines induce the expression of brain cytokines that are produced by resident macrophages and microglial cells. These locally produced cytokines diffuse throughout the brain parenchyma to act on target brain areas so as to organise the central components of the host response to infection (fever, neuroendocrine activation, and sickness behavior).

de Kleijn, D. and G. Pasterkamp (2003). "Toll-like receptors in cardiovascular diseases." Cardiovasc Res 60(1): 58-67.

            The Toll-like receptor family recognizes mostly exogenous ligands like bacterial lipopolysaccharides or DNA and activates the inflammatory cell. Evidence is accumulating that these Toll-like receptors are important in cardiovascular pathologies. Recently, expression of Toll-like receptors in arterial and myocardial cells has been shown and mouse knockout and human studies on polymorphisms point to a role of Toll-like receptor 4 in neointima formation and atherosclerosis. It is now becoming clear that these receptors not only serve as receptors for pathogen-associated molecular patterns but are also involved in the initiation and progression of cardiovascular pathologies.

Devine, D. A. (2003). "Antimicrobial peptides in defence of the oral and respiratory tracts." Mol Immunol 40(7): 431-43.

            Antimicrobial peptides (AMPs) are components of complex host secretions, acting synergistically with other innate defence molecules to combat infection and control resident microbial populations throughout the oral cavity and respiratory tract. AMPs are directly antimicrobial, bind lipopolysaccharide (LPS) and lipoteichoic acid, and are immunomodulatory signals. Pathogenic and commensal organisms display a variety of resistance mechanisms, which are related to structure of cell wall components (e.g. LPS) and cytoplasmic membranes, and peptide breakdown mechanisms. For example, LPS of the AMP-resistant cystic fibrosis pathogen Burkholderia cepacia is under-phosphorylated and highly substituted with charge-neutralising 4-deoxy-4-aminoarabinose. Additionally, host mimicry by addition of phosphorylcholine contributes to resistance in oral and respiratory organisms. Porphyromonas gingivalis, Pseudomonas aeruginosa and other pathogens produce extracellular and membrane-bound proteases that degrade AMPs. Many of these bacterial properties are environmentally regulated. Their modulation in response to host defences and inflammation can result in altered sensitivity to AMPs, and may additionally change other host-microbe interactions, e.g. binding to Toll-like receptors. The diversity and breadth of antimicrobial cover and immunomodulatory function provided by AMPs is central to the ability of a host to respond to the diverse and highly adaptable organisms colonising oral and respiratory mucosa.

Dunne, A. and L. A. O'Neill (2003). "The interleukin-1 receptor/Toll-like receptor superfamily: signal transduction during inflammation and host defense." Sci STKE 2003(171): re3.

            The signal transduction pathways activated by the proinflammatory cytokine interleukin-1 (IL-1) have been the focus of much attention because of the important role that IL-1 plays in inflammatory diseases. A number of proteins have been described that participate in the post-receptor activation of the transcription factor nuclear factor kappaB (NF-kappaB), and stress-activated protein kinases such as p38 mitogen-activated protein kinase (MAPK). It has also emerged that the type I IL-1 receptor (IL-1RI) is a member of an expanding receptor superfamily. These related receptors all have sequence similarity in their cytosolic regions. The family includes the Drosophila melanogaster protein Toll, the IL-18 receptor (IL-18R), and 10 Toll-like receptors (TLRs), TLR-1 to TLR-10, which bind to microbial products, activating host defense responses. Because of the similarity of IL-1RI to Toll, the conserved sequence in the cytosolic region of these proteins has been termed the Toll-IL-1 receptor (TIR) domain. The same proteins activated during signaling by IL-1RI also participate in signaling by other receptors with TIR domains. The receptor superfamily is evolutionarily conserved; members also occur in plants and insects, where they also function in host defense. The signaling proteins that are activated are also conserved across species. Differences are, however, starting to emerge in signaling pathways activated by different receptors. This receptor superfamily, therefore, represents an ancient signaling system that is a critical determinant of the innate immune and inflammatory responses.

Dziarski, R. (2003). "Recognition of bacterial peptidoglycan by the innate immune system." Cell Mol Life Sci 60(9): 1793-804.

            The innate immune system recognizes microorganisms through a series of pattern recognition receptors that are highly conserved in evolution. Peptidoglycan (PGN) is a unique and essential component of the cell wall of virtually all bacteria and is not present in eukaryotes, and thus is an excellent target for the innate immune system. Indeed, higher eukaryotes, including mammals, have several PGN recognition molecules, including CD14, Toll-like receptor 2, a family of peptidoglycan recognition proteins, Nod1 and Nod2, and PGN-lytic enzymes (lysozyme and amidases). These molecules induce host responses to microorganisms or have direct antimicrobial effects.

Elward, K. and P. Gasque (2003). ""Eat me" and "don't eat me" signals govern the innate immune response and tissue repair in the CNS: emphasis on the critical role of the complement system." Mol Immunol 40(2-4): 85-94.

            A full innate immune system (e.g. complement system, scavenger receptors, Toll-like receptors (TLR)) has been described in the CNS and is thought to be an extremely efficient army designed to fight against invading pathogens and toxic cell debris such as apoptotic cells and amyloid fibrils. The binding of soluble or secreted innate immune molecules on pathogen-associated molecular patterns (PAMPs) as well as apoptotic cell-associated molecular patterns (ACAMPs) provide several "eat me" signals to promote the safe disposal of the intruders by professional and amateur phagocytes. These patterns are deciphered by receptors (pattern recognition receptors, PRRs; e.g. CR3) that control phagocytosis and associated inflammatory response depending on the meaning of these signals. Importantly, in order to avoid excessive collateral damage of surrounding cells, it is increasingly evident that "don't eat me" signals (coined herein as self-associated molecular patterns, SAMPs; e.g. complement regulatory proteins, CD200) are of paramount importance to signal a robust anti-inflammatory response and promote tissue repair. Further knowledge of the innate immune response in the CNS will greatly help to delineate the novel therapeutic routes to protect from CNS inflammation and neurodegeneration.

Emonts, M., J. A. Hazelzet, et al. (2003). "Host genetic determinants of Neisseria meningitidis infections." Lancet Infect Dis 3(9): 565-77.

            The clinical presentation of infections caused by Neisseria meningitidis is highly diverse. Some patients develop meningitis, and others present with sepsis or even septic shock. After invasion of the bloodstream by the bacteria, three main cascade pathways are activated. These are the complement system, the inflammatory response, and the coagulation and fibrinolysis pathway. These pathways do not act independently but are able to interact with each other. Genetic polymorphisms among components of these pathways have been shown to be involved in the susceptibility, severity, and outcome of meningococcal disease. We review knowledge of genetic variations associated with susceptibility to and severity of meningococcal infection. Complement deficiencies and defects in sensing or opsonophagocytic pathways, such as the rare Toll-like receptor 4 single nucleotide polymorphisms (SNPs) and combinations of inefficient variants of Fcgamma-receptors, seem to have the most important role in genetically established susceptibility. Effect on severity has repeatedly been reported for FcgammaRIIa and plasminogen activator inhibitor type 1 (PAI1) polymorphisms. Outcome effects have been confirmed for SNPs in properdin deficiencies, PAI1 and combination of the -511C/T SNP in interleukin 1beta, and the +2018C/T SNP in interleukin RN. Conflicting results are reported for the effect of the -308G/A promoter polymorphism in tumour necrosis factor (TNF) alpha. These differences may reflect discrepancies in group definitions between studies or the influence of additional SNPs in the TNFalpha promoter, which can form haplotypes representing different cytokine production capacity. For several SNPs, the potential effect on susceptibility, severity, or outcome has not yet been confirmed in an independent study.

Espevik, T., E. Latz, et al. (2003). "Cell distributions and functions of Toll-like receptor 4 studied by fluorescent gene constructs." Scand J Infect Dis 35(9): 660-4.

            Bacterial lipopolysaccharide (LPS) is recognized in mammals by a receptor complex composed of CD14, Toll-like receptor 4 (TLR4), and MD-2. The detailed mechanisms of how TLR4 transmits the signal from the outside to the inside of the cell remain to be elucidated. One way of studying TLR4 signaling mechanisms is to construct chimeras of TLR molecules C-terminally fused to fluorescent proteins and stably express these constructs in cells. Such constructs are functional when transfected into HEK293 epithelial cells. Confocal microscopy of TLR4 expression in live cells demonstrated pronounced expression on the plasma membrane as well in the Golgi apparatus. Studies were performed to clarify whether expression of TLR4 in the Golgi was necessary for LPS stimulation. Rapid recycling of TLR4/CD14/MD-2 complexes between the Golgi and the plasma membrane was a prominent phenomenon. In agreement with other types of plasma membrane receptors, aggregation of TLR4 by immobilized TLR4 antibodies was sufficient to induce signaling. Also, pharmacological disruption of the Golgi did not inhibit LPS induced NF-kappaB activation. Furthermore, LPS stimulation recruited the adapter molecule, MyD88, to the inside of the plasma membrane. Thus, LPS signaling commences on the plasma membrane and is independent of trafficking to the Golgi.

Evans, J. T., C. W. Cluff, et al. (2003). "Enhancement of antigen-specific immunity via the TLR4 ligands MPL adjuvant and Ribi.529." Expert Rev Vaccines 2(2): 219-29.

            MPL (Corixa) adjuvant is a chemically modified derivative of lipopolysaccharide that displays greatly reduced toxicity while maintaining most of the immunostimulatory activity of lipopolysaccharide. MPL adjuvant has been used extensively in clinical trials as a component in prophylactic and therapeutic vaccines targeting infectious disease, cancer and allergies. With over 33,000 doses administered to date, MPL adjuvant has emerged as a safe and effective vaccine adjuvant. Recently, scientists at Corixa Corporation have developed a library of synthetic lipid A mimetics (aminoalkyl glucosaminide 4-phosphates) with demonstrated immunostimulatory properties. Similar to MPL adjuvant, these synthetic compounds signal through Toll-like receptor 4 to stimulate the innate immune system. One of these compounds, Ribi.529 (RC-529), has emerged as a leading adjuvant with a similar efficacy and safety profile to MPL adjuvant in both preclinical and clinical studies.

Fondevila, C., R. W. Busuttil, et al. (2003). "Hepatic ischemia/reperfusion injury--a fresh look." Exp Mol Pathol 74(2): 86-93.

            Ischemia/reperfusion (I/R) injury is a multifactorial process that affects graft function after liver transplantation. An understanding of the mechanisms involved in I/R injury is essential for the design of therapeutic strategies to improve the outcome of liver transplantation. The generation of reactive oxygen species subsequent to reoxygenation inflicts tissue damage and initiates a cascade of deleterious cellular responses leading to inflammation, cell death, and ultimate organ failure. Increased experimental evidence has suggested that Kupffer cells and T cells mediate the activation of neutrophil inflammatory responses. Activated neutrophils infiltrate the injured liver in parallel with increased expression of adhesion molecules on endothelial cells. The heme oxygenase system is among the most critical of the cytoprotective mechanisms activated during cellular stress, exerting antioxidant and anti-inflammatory functions, modulating the cell cycle, and maintaining the microcirculation. Finally, the activation of toll-like receptors on Kupffer cells may play a fundamental role in exploring new therapeutic strategies based on the concept that hepatic I/R injury represents a case for a host "innate" immunity.

Fukao, T. and S. Koyasu (2003). "PI3K and negative regulation of TLR signaling." Trends Immunol 24(7): 358-63.

            Excessive immune responses are detrimental to the host and negative feedback regulation is crucial for the maintenance of immune-system integrity. Recent studies have shown that phosphoinositide 3-kinase (PI3K) is an endogenous suppressor of interleukin-12 (IL-12) production triggered by Toll-like receptor (TLR) signaling and limits excessive Th1 polarization. Unlike IRAK-M (IL-1 receptor-associated kinase-M) and SOCS-1 (suppressor of cytokine signaling-1) that are induced by TLR signaling and function during the second or continuous exposure to stimulation, PI3K functions at the early phase of TLR signaling and modulates the magnitude of the primary activation. Thus, PI3K, IRAK-M and SOCS-1 have unique roles in the gate-keeping system, preventing excessive innate immune responses.

Geijtenbeek, T. B. and Y. van Kooyk (2003). "Pathogens target DC-SIGN to influence their fate DC-SIGN functions as a pathogen receptor with broad specificity." Apmis 111(7-8): 698-714.

            Dendritic cells (DC) are vital in the defense against pathogens. To sense pathogens DC express pathogen recognition receptors such as toll-like receptors (TLR) and C-type lectins that recognize different fragments of pathogens, and subsequently activate or present pathogen fragments to T cells. It is now becoming evident that some pathogens subvert DC functions to escape immune surveillance. HIV-1 targets the DC-specific C-type lectin DC-SIGN to hijack DC for viral dissemination. HIV-1 binding to DC-SIGN protects HIV-1 from antigen processing and facilitates its transport to lymphoid tissues, where DC-SIGN promotes HIV-1 infection of T cells. Recent studies demonstrate that DC-SIGN is a more universal pathogen receptor that also recognizes Ebola, cytomegalovirus and mycobacteria. Mycobacterium tuberculosis targets DC-SIGN by a mechanism that is distinct from that of HIV-1, leading to inhibition of the immunostimulatory function of DC and pathogen survival. Thus, a better understanding of DC-SIGN-pathogen interactions and their effects on DC function is necessary to combat infections.

Gewirtz, A. T. (2003). "Intestinal epithelial toll-like receptors: to protect. And serve?" Curr Pharm Des 9(1): 1-5.

            The innate immune system uses a series of pattern recognition receptors to detect the presence of pathogens thus allowing for rapid host defense responses to invading microbes. A key component of such receptors are the "toll-like receptors" (TLRs), which recognize a panel of microbial molecules that tend to be somewhat invariant, at least in select regions, thus permitting a relatively small number of receptors to recognize a large number of different microbes. Accordingly, this panel of TLRs bears little ability to distinguish between commensal and pathogenic microbes as such organisms generally bear far more structural similarities than differences between them. For the professional phagocytic cells classically considered to be the primary mediators of innate immunity such distinction between commensal and pathogenic microbes is not particularly important since any microbe that breaches the outer host defensive barriers to reach these phagocytes, whether doing so by a pathogen-specific or opportunistic mechanism, is likely potentially hazardous to its host. However, epithelial cells that line mucosal surfaces, thus being on the front line of host defense, also play an active role in innate immunity particularly by secreting chemokines and other immune mediators in response to pathogenic microbes. Epithelial cells have been reported to express several TLRs suggesting these receptors play a role in intestinal epithelial innate immune signaling pathways. However, since some mucosal surfaces such as the intestinal epithelium are normally densely colonized by a wide variety of microbes, the ability to distinguish the occasional pathogen from the sea of commensals presents an important challenge. This minireview considers the current findings regarding TLR expression in the intestinal epithelium and the role these receptors might serve in host defense.

Hackett, C. J. (2003). "Innate immune activation as a broad-spectrum biodefense strategy: prospects and research challenges." J Allergy Clin Immunol 112(4): 686-94.

            Biodefense strategies require protection against a broad and largely unforeseen spectrum of pathogens--the forte of innate immune system defenses--that have evolved over millennia to function within moments of encountering either ancient or newly emerging pathogens. Although constitutive, the innate immune system is activated by the presence of microbes or their products, providing a rationale for a potential biodefense strategy. Both prophylactic and postexposure strategies involving innate immune stimulation have been shown to be plausible to prevent or ameliorate infections in animal models. Innate immune-activating compounds based on conserved microbial components recognized by toll-like molecules and other receptors could be synthesized and delivered like drugs by using an entirely different strategy from conventional vaccination. However, important theoretic and practical questions emerge about developing and deploying innate immune protective strategies for biodefense. This rostrum discusses prospects and problems in the overall approach itself. Important topics include microbe-specific issues about innate immune system effectiveness against highly virulent pathogens and general questions, such as whether innate immune responses will be safe and effective if used in a diverse human population of different age groups and with different genetic makeups.

Heine, H. and E. Lien (2003). "Toll-like receptors and their function in innate and adaptive immunity." Int Arch Allergy Immunol 130(3): 180-92.

            Over the past 3 years our knowledge about how we sense the microbial world has been fundamentally changed. It has been known for decades that microbial products, such as lipopolysaccharide, lipoproteins, or peptidoglycan, have a profound activity on human cells. Whereas the structure of many different pathogenic microbial compounds has been extensively studied and characterized, the molecular basis of their recognition by the cells of the innate immune system remained elusive for a long time. It was Charles Janeway [Cold Spring Harb Symp Quant Biol 1989;54/1:1-13] who developed the idea of microbial structures forming pathogen-associated molecular patterns that would be recognized by pattern recognition receptors. The discovery of the family of Toll receptors in species as diverse as DROSOPHILA and humans, and the recognition of their role in distinguishing molecular patterns that are common to microorganisms have led to a renewed appreciation of the innate immune system. Moreover, it is now clear that the activation of the innate immune system through mammalian Toll-like receptors has also an instructive role for the responses of the adaptive immune response and, thus, may influence allergic diseases such as asthma.

Hertz, C. J. and R. L. Modlin (2003). "Role of toll-like receptors in response to bacterial infection." Contrib Microbiol 10: 149-63.

Holmgren, J., A. M. Harandi, et al. (2003). "Mucosal adjuvants and anti-infection and anti-immunopathology vaccines based on cholera toxin, cholera toxin B subunit and CpG DNA." Expert Rev Vaccines 2(2): 205-17.

            The mucosal immune system consists of an integrated network of lymphoid cells that work in concert with innate host factors to promote host defence. Mucosal immunization can be used both to protect the mucosal surfaces against colonization and invasion by microbial pathogens and to provide a means for immunological treatment of selected autoimmune, allergic or infectious-immunopathological disorders through the induction of antigen-specific tolerance. The development of mucosal vaccines, whether for prevention of infectious diseases or for oral tolerance immunotherapy, requires efficient antigen delivery and adjuvant systems. Significant progress has recently been made to generate partly or wholly detoxified derivatives of cholera toxin (including the completely nontoxic cholera toxin B subunit) and the closely related Escherichia coli heat-labile enterotoxin, with retained adjuvant activity. Cholera toxin B subunit is a protective component of a widely registered oral vaccine against cholera, and has proven to be a promising vector for either giving rise to anti-infective immunity or for inducing peripheral anti-inflammatory tolerance to chemically or genetically linked foreign antigens administered mucosally. Promising advances have also recently been made in the design of efficient mucosal adjuvants based on bacterial DNA that contains CpG-motifs and various imidazoquinoline compounds binding to different Toll-like receptors on mucosal antigen-presenting cells.

Janssens, S. and R. Beyaert (2003). "Functional diversity and regulation of different interleukin-1 receptor-associated kinase (IRAK) family members." Mol Cell 11(2): 293-302.

            Interleukin-1 receptor-associated kinase (IRAK) was first described as a signal transducer for the proinflammatory cytokine interleukin-1 (IL-1) and was later implicated in signal transduction of other members of the Toll-like receptor (TLR)/IL-1 receptor (IL-1R) family. In the meantime, four different IRAK-like molecules have been identified: two active kinases, IRAK-1 and IRAK-4, and two inactive kinases, IRAK-2 and IRAK-M. All IRAKs mediate activation of nuclear factor-kappaB (NF-kappaB) and mitogen-activated protein kinase (MAPK) pathways. Although earlier observations suggested that IRAKs have redundant functions, this hypothesis is now challenged by knockout studies. Furthermore, recent data imply a role for IRAK-1 in tumor necrosis factor receptor (TNFR) superfamily-induced signaling pathways as well. The scope of this review is to highlight the specific role of different IRAKs and to discuss several mechanisms that contribute to their activation and regulation.

Jiang, W. and D. S. Pisetsky (2003). "Enhancing immunogenicity by CpG DNA." Curr Opin Mol Ther 5(2): 180-5.

            Bacterial DNA and oligonucleotides containing unmethylated CpG dinucleotides (CpG DNA) can stimulate immune responses and have potential for use as novel agents to enhance immunogenicity. CpG DNA can interact with toll-like receptor 9 and cause activation through a myeloid differentiation primary response gene (MyD88)-dependent signaling pathway. Due to its pattern of immune cell activation, CpG DNA can induce a cytokine milieu to promote T-helper cell responses and serve as an adjuvant. Furthermore, CpG DNA can provide protection against pathogens in animal models and has therapeutic applications in clinical settings such as in cancer and allergy.

Kaisho, T. and S. Akira (2003). "Regulation of dendritic cell function through Toll-like receptors." Curr Mol Med 3(4): 373-85.

            Higher animals establish host defense by orchestrating innate and adaptive immunity. This is mediated by professional antigen presenting cells, i.e. dendritic cells (DCs). DCs can incorporate pathogens, produce a variety of cytokines, maturate, and present pathogen-derived peptides to T cells, thereby inducing T cell activation and differentiation. These responses are triggered by microbial recognition through type I transmembrane proteins, Toll-like receptors (TLRs) on DCs. TLRs consist of ten members and each TLR is involved in recognizing a variety of microorganism-derived molecular structures. TLR ligands include cell wall components, proteins, nucleic acids, and synthetic chemical compounds, all of which can activate DCs as immune adjuvants. Each TLR can activate DCs in a similar, but distinct manner. For example, TLRs can be divided into subgroups according to their type I interferon (IFN) inducing ability. TLR2 cannot induce IFN-alpha or IFN-beta, but TLR4 can lead to IFN-beta production. Meanwhile, TLR3, TLR7, and TLR9 can induce both IFN-alpha and IFN-beta. Recent evidences suggest that cytoplamic adapters for TLRs are especially crucial for this functional heterogeneity. Clarifying how DC function is regulated by TLRs should provide us with critical information for manipulating the host defense against a variety of diseases.

Kauffman, H. F. and S. van der Heide (2003). "Exposure, sensitization, and mechanisms of fungus-induced asthma." Curr Allergy Asthma Rep 3(5): 430-7.

            Healthy individuals are continuously exposed to fungal biomass, which includes live and dead spores and fungal debris that is entrapped in the airways. In patients with asthma and/or atopy, exposure to fungal biomass might result in age-dependent sensitization and asthmatic reactions. Interaction with Toll-like receptors (TLRs) of the innate immune defense (alveolar macrophages and epithelial cells) and protease-activated receptors (PARs) determine the effectiveness of elimination of fungal material. The association of sensitization to Alternaria with severe asthma is discussed in relation to the age-dependent sensitization, rate of release of allergens from spores, and activity of its proteases. A model is described concerning the influence of polymorphic genes for airway hyperresponsiveness (AHR) and atopy, showing a cumulating influence on susceptibility for allergen-induced asthma, and explaining that fungus-induced airway obstruction is mainly associated with more severe asthma.

Kauffman, H. F. (2003). "Interaction of environmental allergens with airway epithelium as a key component of asthma." Curr Allergy Asthma Rep 3(2): 101-8.

            Epithelial cells in the airway wall actively interact with environmental antigens/allergens, both in healthy individuals and patients with asthma. In patients with (allergic) asthma, the epithelium is abnormal, showing damaged structures and continuous activation similar to a repair phenotype cell. Epithelial cells bind allergens by a diversity of innate receptors, similar and in part identical to the Toll-like receptor family, which can induce the release of cytokines, chemokines, and growth factors. Protease-containing extracts (house dust mite, fungi) may additionally cause damage of the epithelial cell layer, thereby enhancing the repair phenotype of epithelial cells in patients with asthma. These interactions may result in facilitation of transport of allergens and enhanced presentation to the immune system (Th2-type response). The inflammatory response induces a second phase of Th2-type cytokines and cytotoxic products that will enhance growth factor-mediated airway remodeling, as is found in asthma. An understanding of the largely unknown innate responses of epithelial cells with environmental antigens/allergens may open new treatment modalities for asthma and other airway diseases.

Kiechl, S., C. J. Wiedermann, et al. (2003). "Toll-like receptor 4 and atherogenesis." Ann Med 35(3): 164-71.

            Toll-like receptor 4 (TLR4) is a pattern recognition receptor involved in the innate immune response to various microorganisms and other exogenous and endogenous stress factors. Recently, evidence emerged that important inflammatory processes implicit in human atherogenesis are mediated in part via the TLR4/nuclear factor-kappaB pathway. Polymorphisms of TLR4, which attenuate receptor signalling, enhance the risk of acute severe infections but may have opposite effects on atherogenesis. The aim of this review is to critically discuss current experimental and epidemiological evidence for a role of TLR4 in atherogenesis and to highlight the main controversies and perspectives in this emerging field of vascular biology.

Kimoto, M., K. Nagasawa, et al. (2003). "Role of TLR4/MD-2 and RP105/MD-1 in innate recognition of lipopolysaccharide." Scand J Infect Dis 35(9): 568-72.

            TLR4 and RP105 are unique members of the Toll-like receptor (TLR) family molecules. They are associated with small molecules called MD-2 and MD-1, respectively, to form heterodimers (TLR4/MD-2 and RP105/MD-1) and function as recognition/signaling molecules of lipopolysaccharide (LPS), a membrane component of Gram-negative bacteria. Analysis of transfectant cell lines and gene-targeted mice revealed that both MD-2 and MD-1 are involved in the recognition of LPS as well as in the regulation of intracellular distribution and the surface expression of TLR4 and RP105, respectively. Since RP105 or MD-1-deficient mice show a reduced but not complete lack of LPS responsiveness, there may be functional associations between TLR4/MD-2 and RP105/MD-1. In addition, there was an increased frequency of RP105-negative B-lymphocytes in the peripheral blood in several rheumatic diseases, such as systemic lupus erythematosus, suggesting the involvement of RP105 in the pathophysiology of autoimmunity. Further analysis of the structure and function of TLR4/MD-2 and RP105/MD-1 will provide a better understanding of the pathophysiology, and a chance to develop evidence-based treatments for septic shock syndrome and autoimmunity.

Lakhani, S. A. and C. W. Bogue (2003). "Toll-like receptor signaling in sepsis." Curr Opin Pediatr 15(3): 278-82.

            Despite extensive research, bacterial sepsis and its associated systemic inflammation remain a major cause of morbidity and mortality in the pediatric intensive care unit. Advances in molecular biology, however, have improved our understanding of this disease process and have opened up new avenues of potential therapeutic approaches. One such exciting area has been the substantial and still growing evidence that the mammalian immune system uses a family of Toll-like receptors (TLRs) to generate a response to molecular patterns present on invading microorganisms. In particular, TLR4 is part of a recognition complex for bacterial lipopolysaccharide (LPS), thus raising the likelihood of its involvement in the inflammatory response to bacterial sepsis. This review highlights our understanding of the molecular biology of these receptors, focusing on the LPS response, and concluding with a summary of ongoing evaluation and potential therapeutic strategies for treating sepsis through blockade of TLR signaling.

Marciani, D. J. (2003). "Vaccine adjuvants: role and mechanisms of action in vaccine immunogenicity." Drug Discov Today 8(20): 934-43.

            Inactivated vaccines require adjuvants to stimulate an immune response. The choice of adjuvant or immune enhancer determines whether the immune response is effective, ineffective or damaging. Accordingly, there is a need for new adjuvants that stimulate the appropriate immunity, for example, T cell immunity for intracellular pathogens and cancer vaccines. In several adjuvants, the identification of chemical groups that interact with specific cell toll-like receptors (innate immunity) or receptors for co-stimulatory ligands (adaptive immunity), has enabled the establishment of structure-function relationships that are useful in the design of new adjuvants. Because of the crucial immunomodulating role of adjuvants, sub-unit vaccine development will remain dependent on new adjuvants.

Marshall, J. S., J. D. McCurdy, et al. (2003). "Toll-like receptor-mediated activation of mast cells: implications for allergic disease?" Int Arch Allergy Immunol 132(2): 87-97.

            Toll-like receptors have a critical role in innate immunity and host defence. However their role in allergic disease has not been studied in great detail. The presence of these receptors on mast cells opens up new possibilities concerning the role of Toll-like receptors in the pathogenesis of asthma and atopic dermatitis. The current review examines the biology of Toll-like receptors expressed on mast cells. In particular, mast cell expression of Toll-like receptors and the diverse responses observed following Toll-like receptor-mediated activation are considered. Several pathogens such as Staphylococcus aureus and respiratory syncytial virus are known to contribute to the development or maintenance of allergic disease and also express potent activators of the Toll-like receptor pathways. The importance of such interactions and the full role of pathogens in chronic allergic disease remain to be elucidated. The unusual ability of Toll-like receptor 2 activators to selectively induce leukotriene production by mast cells opens up new possibilities concerning mechanisms of disease exacerbation during infection.

Miyake, K. (2003). "[Toll-like receptors and their roles in defense responses against infection]." Kansenshogaku Zasshi 77(7): 473-9.

Miyake, K. (2003). "Innate recognition of lipopolysaccharide by CD14 and toll-like receptor 4-MD-2: unique roles for MD-2." Int Immunopharmacol 3(1): 119-28.

            Adaptive immunity generally refers to the ability of lymphocytes to recognize microbial, viral and fungal proteins via T cell receptors and antibodies. More ancestral and widespread innate immune mechanisms include those responsible for recognition of microbial glycolipids. Lipopolysaccharide (LPS) is the best studied, and arguably one of the most important of bacterial products because of its role in innate immune responses and endotoxin-mediated sepsis. Converging studies in two independent fields have recently led to the identification of LPS recognition molecules utilized by mammalian cells. Toll-like receptor 4 (TLR4) was identified as a mammalian homologue of the Toll receptor, which recognized fungi in the Drosophila's immune system. Spontaneous and targeted mutations identified TLR4 as an LPS recognition molecule. Separate studies of a Radioprotective 105 (RP105) and MD-1 heterodimer expressed by cells led to the identification of MD-2 as a molecule associated with TLR4. Very recent in vivo studies have now revealed an essential contribution of MD-2 to LPS recognition. These findings further our understanding of protective, as well as detrimental innate immune mechanisms and may lead to new therapies for endotoxin shock.

Moncada, D. M., S. J. Kammanadiminti, et al. (2003). "Mucin and Toll-like receptors in host defense against intestinal parasites." Trends Parasitol 19(7): 305-11.

            Gastrointestinal mucin is a constituent of luminal barrier function and is the first line of host defense against invading pathogens. Mucin carbohydrates and amino acids, as well as trapped soluble host defense molecules, serve as substrates for colonization and control or deter pathogen invasion to the underlying mucosal epithelial cells. Toll-like receptors on the surface of epithelial cells act as sensors for invading pathogens, and the ensuing host response limits parasite invasion and leads to adaptive immunity. The latest work in the field and the use of parasite model systems to illustrate the delicate host-parasite interaction at the mucosal surface of the gut are discussed here.

Moreillon, P. and P. A. Majcherczyk (2003). "Proinflammatory activity of cell-wall constituents from gram-positive bacteria." Scand J Infect Dis 35(9): 632-41.

            Innate immunity reacts to conserved bacterial molecules. The outermost lipopolysaccharide (LPS) of Gram-negative organisms is highly inflammatory. It activates responsive cells via specific CD14 and toll-like receptor-4 (TLR4) surface receptor and co-receptors. Gram-positive bacteria do not contain LPS, but carry surface teichoic acids, lipoteichoic acids and peptidoglycan instead. Among these, the thick peptidoglycan is the most conserved. It also triggers cytokine release via CD14, but uses the TLR2 co-receptor instead of TLR4 used by LPS. Moreover, whole peptidoglycan is 1000-fold less active than LPS in a weight-to-weight ratio. This suggests either that it is not important for inflammation, or that only part of it is reactive while the rest acts as ballast. Biochemical dissection of Staphylococcus aureus and Streptococcus pneumoniae cell walls indicates that the second assumption is correct. Long, soluble peptidoglycan chains (approximately 125 kDa) are poorly active. Hydrolysing these chains to their minimal unit (2 sugars and a stem peptide) completely abrogates inflammation. Enzymatic dissection of the pneumococcal wall generated a mixture of highly active fragments, constituted of trimeric stem peptides, and poorly active fragments, constituted of simple monomers and dimers or highly polymerized structures. Hence, the optimal constraint for activation might be 3 cross-linked stem peptides. The importance of structural constraint was demonstrated in additional studies. For example, replacing the first L-alanine in the stem peptide with a D-alanine totally abrogated inflammation in experimental meningitis. Likewise, modifying the D-alanine decorations of lipoteichoic acids with L-alanine, or deacylating them from their diacylglycerol lipid anchor also decreased the inflammatory response. Thus, although considered as a broad-spectrum pattern-recognizing system, innate immunity can detect very subtle differences in Gram-positive walls. This high specificity underlines the importance of using well-characterized microbial material in investigating the system.

Nagy, L. E. (2003). "Recent insights into the role of the innate immune system in the development of alcoholic liver disease." Exp Biol Med (Maywood) 228(8): 882-90.

            The innate immune system is responsible for the rapid, initial response of the organism to potentially dangerous stresses, including pathogens, tissue injury, and malignancy. Pattern-recognition receptors of the toll-like receptor (TLR) family expressed by macrophages provide a first line of defense against microbial invasion. Activation of these receptors results in a stimulus-specific expression of genes required to control the infection, including the production of inflammatory cytokines and chemokines, followed by the recruitment of neutrophils to the site of infection. The early stages in the development of alcoholic liver disease (ALD) follow a pattern characteristic of an innate immune response. Kupffer cells, the resident macrophages in the liver, are activated in response to bacterial endotoxins (lipopolysaccharide, LPS), leading to the production of inflammatory and fibrogenic cytokines, reactive oxygen species, as well as the recruitment of neutrophils to the liver. One mechanism by which chronic ethanol can turn the highly regulated innate immune response into a pathway of disease is by disrupting the signal transduction cascades mediating the innate immune response. Recent studies have identified specific modules in the TLR-4 signaling cascade that are disrupted after chronic ethanol exposure, including CD14 and the mitogen-activated protein kinase family members, ERK1/2 and p38. Enhanced activation of these TLR-4 dependent signaling pathways after chronic ethanol likely contributes to the development of alcoholic liver disease.

O'Neill, L. A. (2003). "Therapeutic targeting of Toll-like receptors for inflammatory and infectious diseases." Curr Opin Pharmacol 3(4): 396-403.

            Roles for Toll-like receptors (TLRs) are emerging in conditions such as sepsis syndrome, systemic lupus erythromatosis, rheumatoid arthritis and asthma, suggesting that the selective targeting of TLRs might be useful therapeutically. TLRs are defined by the presence of extracellular leucine-rich repeats and an intracellular Toll/interleukin-1 receptor domain, and play a role in host defence and inflammation. Signalling pathways activated by TLRs show remarkable similarity to those activated by the pro-inflammatory cytokine interleukin-1 (the receptor for which also has a Toll/interleukin-1 receptor domain), although adaptor proteins specific for certain TLRs are starting to emerge (e.g. Mal and Trif). The common signalling pathways used by all members of the TLR superfamily are being targeted, with drugs that block nuclear factor-kappaB and p38 mitogen-activated protein kinase in clinical development for diseases such as rheumatoid arthritis and psoriasis. As we learn more about TLR signal transduction, more options are presenting themselves for pharmacological targeting.

O'Neill, L. A., K. A. Fitzgerald, et al. (2003). "The Toll-IL-1 receptor adaptor family grows to five members." Trends Immunol 24(6): 286-90.

            Toll-like receptor (TLR) signal transduction is mediated by an adaptor protein termed MyD88. In the case of TLR2 and TLR4, another adaptor related to MyD88 called Mal also participates in signalling. Two recent papers have added a third adaptor to the family, called Toll-interleukin-1 receptor (TIR) domain-containing adaptor inducing interferon-beta (IFN-beta) (TRIF) or TIR-containing adaptor molecule-1 (TICAM-1), which is particularly important for IFN regulatory factor-3 (IRF-3) activation by antiviral TLR3. Two additional adaptors are present in humans, termed Trif-related adaptor molecule (TRAM) and sterile alpha and HEAT-Armadillo motifs (SARM). It is probable that differential use of adaptors will help explain the distinct pathways activated by TLRs during host defence.

O'Neill, L. A., A. Dunne, et al. (2003). "Mal and MyD88: adapter proteins involved in signal transduction by Toll-like receptors." J Endotoxin Res 9(1): 55-9.

            Signal transduction processes activated by Toll-like receptors (TLRs) include the important transcription factor NF-kappaB and 2 MAP kinases, p38 and Jun N-terminal kinase. These signals ultimately give rise to increased expression of a multitude of pro-inflammatory proteins. Receptor-proximal proteins involved in signalling by all TLRs include the adapter MyD88, 3 IRAKs (IRAK-4, IRAK and IRAK-2), Tollip, Traf-6 and TAK-1. Differences between signals generated by TLRs are emerging, with both TLR4 and TLR2 signalling requiring an additional adapter termed MyD88-adapter-like (Mal; also known as TIRAP). MyD88 and Mal both have a homologous Toll/IL-1 receptor (TIR) domain although they differ in their N-termini, with MyD88 possessing a death domain. In addition, structural models reveal marked differences in surface charges which, when taken with surface charge differences between TLR2 and TLR4 TIR domains, may indicate that TLR4 but not TLR2 recruits Mal directly. Another difference is that Mal can become phosphorylated. Future studies on Mal will reveal specificities in signal transduction by different TLRs, which may ultimately provide molecular explanations for specificities in the innate immune response to infection.

Qureshi, S. T. and R. Medzhitov (2003). "Toll-like receptors and their role in experimental models of microbial infection." Genes Immun 4(2): 87-94.

            Effective host defense against microbial infection depends upon prompt recognition of pathogens, activation of immediate containment measures, and ultimately the generation of a specific and definitive adaptive immune response. The innate immune system of the host is responsible for providing constant surveillance against infection; when confronted by pathogens it deploys a series of rapidly acting antimicrobial effectors while simultaneously instructing the adaptive immune system as to the nature and context of the infectious threat. Pathogen recognition and activation of innate immunity is mediated by members of the Toll-like receptor (TLR) family through detection of conserved microbial structures that are absent from the host. Experimental models of infection using TLR-deficient mice, as well as limited human studies, have clearly demonstrated the critical role of TLRs in host defense against most major groups of mammalian pathogens.

Rassa, J. C. and S. R. Ross (2003). "Viruses and Toll-like receptors." Microbes Infect 5(11): 961-8.

            Recently a number of viruses, including a poxvirus, herpesvirus, retrovirus and two paramyxoviruses, have been shown to activate cells via Toll-like receptor family members. Here we postulate that although activation via Toll-like receptor molecules can lead to anti-viral innate immune responses, in some cases viruses may use these responses to ameliorate infection.

Reis e Sousa, C., S. D. Diebold, et al. (2003). "Regulation of dendritic cell function by microbial stimuli." Pathol Biol (Paris) 51(2): 67-8.

            Dendritic cells (DC) initiate T cell responses and produce cytokines and other molecules that can regulate the class adaptive immunity. It is increasingly clear that DC in vivo are in a "resting" state and require exogenous signals to transit into an "effector" state in which they can prime T cells. Much of this DC activation process appears to be regulated by infection. Exposure of murine DC to certain pathogens or their products triggers DC migration to T cell areas of secondary lymphoid tissues, improves MHC presentation and increases DC co-stimulatory potential. Pathogen recognition can also initiate cytokine production and/or condition DC to produce cytokines in response to subsequent T cell feedback signals delivered via CD40 and similar receptors. Recognition of pathogens by DC is largely dependent on Toll-like receptors (TLRs). Interestingly, mouse splenic CD8alpha+ and CDalpha-CD4- DC have the ability to produce either IL-12 p70 or IL-10 depending on the nature of the pathogen encountered. In contrast, CD4+ DC seem incapable of producing IL-12 p70. Thus, the nature of the pathogen can dictate the type of cytokine that is made by some DC subsets, allowing them to prime distinct types of immune responses. Overall, DC display significant plasticity in their ability to respond to infection and direct adaptive immunity.

Rivest, S. (2003). "Molecular insights on the cerebral innate immune system." Brain Behav Immun 17(1): 13-9.

            All species need an immediate reply to the microbial pathogens that is part of an effective immune response and is essential for the survival of most organisms. This reply is known as the innate immune response and is characterized by the de novo production of mediators that either kill the microbes directly or activate phagocytic cells to ingest and kill them. The innate immune response can be driven through specific recognition systems, the best example being an interaction between the endotoxin lipopolysaccharide (LPS) and its receptors CD14 and Toll-like receptor 4 (TLR4). For a long time, the brain was considered to be a privileged organ from an immunological point of view, owing to its inability to mount an immune response and process antigens. Although this is partly true, the CNS shows a well-organized innate immune reaction in response to systemic bacterial infection and cerebral injury. The CD14 and TLR4 receptors are constitutively expressed in the circumventricular organs (CVOs), choroid plexus and leptomeninges. Circulating LPS is able to cause a rapid transcriptional activation of genes encoding CD14 and TLR2, as well as a wide variety of pro-inflammatory molecules in CVOs. A delayed response to LPS takes place in cells located at boundaries of the CVOs and in microglia across the CNS. Therefore, without having direct access to the brain parenchyma, pathogens have the ability to trigger an innate immune reaction throughout cerebral tissue. This review presents evidence supporting the existence of such a system in the brain, which is finely regulated at the transcription level. Transient activation of this system is not harmful toward neuronal elements.

Romics, L., Jr., G. Frendl, et al. (2003). "[Cellular and molecular changes of the liver in sepsis and in systemic inflammatory response syndrome (SIRS)]." Orv Hetil 144(11): 499-506.

            This paper provides a review on the changes in the molecular and cellular level of the liver during sepsis and systemic immune response syndrome. The different function of the various liver cells and their mediators are analyzed. Dual role of nitric-oxide and carbon-monoxide are discussed followed by an overview about acute phase proteins and heat shock proteins in septic liver. A detailed description is presented on the role of the Toll-like receptors and their signaling pathways in the liver during sepsis and systemic immune response syndrome. Finally, the possible mechanisms leading to apoptosis of the liver cells are shown and the most recent therapeutical challenges are discussed.

Rothenfusser, S., E. Tuma, et al. (2003). "Recent advances in immunostimulatory CpG oligonucleotides." Curr Opin Mol Ther 5(2): 98-106.

            The vertebrate immune system has evolved a mechanism to detect CpG motifs within microbial DNA (CpG DNA). Synthetic oligonucleotides containing CpG motifs (CpG ODNs) are potent immunomodulatory molecules and outstanding vaccine adjuvants. A number of recent findings have greatly improved our understanding of the biology of CpG DNA, and the immunological effects of CpG DNA are now recognized to be distinct in mouse and human. The plasmacytoid dendritic cell (PDC) was identified to play a pivotal role in mediating CpG-induced immune responses. So far, the B-cell is the only other immune cell subset in humans besides the PDC, equipped with the toll-like receptor-9 to detect CpG motifs. The information on these two prime CpG-sensitive cells has allowed the identification of novel CpG ODNs with distinct functional activity. Together with exciting contributions from animal studies, the way seems to be paved for the successful clinical development of this novel class of molecular therapeutics.

Sabroe, I., R. C. Read, et al. (2003). "Toll-like receptors in health and disease: complex questions remain." J Immunol 171(4): 1630-5.

Schwarz, K., T. Storni, et al. (2003). "Role of Toll-like receptors in costimulating cytotoxic T cell responses." Eur J Immunol 33(6): 1465-70.

            Stimulation of Toll-like receptors (TLR) by pathogen-derived compounds leads to activation of APC, facilitating the induction of protective immunity. This phenomenon is the basis of most adjuvant formulations currently in development. Here, we tested the ability of TLR2, 3, 4, 5, 7 and 9 signaling to enhance CTL responses upon vaccination with virus-like particles. Stimulation of TLR2 and 4 failed to increase CTL responses, whereas ligands for TLR3, 5 and 7 exhibited moderate adjuvant function. In contrast, stimulation of TLR9 dramatically increased CTL responses, indicating that ligands for TLR9 are likely to be the most promising candidates for the development of novel adjuvant formulations for stimulating CTL responses.

Seya, T., T. Akazawa, et al. (2003). "Role of toll-like receptors and their adaptors in adjuvant immunotherapy for cancer." Anticancer Res 23(6a): 4369-76.

            The potentiation of immune responses to tumor-associated antigen (Ag) is a pivotal issue in immunotherapy for cancer and thus requires the use of adjuvants, which are involved in efficient antibody (Ab) production and killer cell induction. The efficacy for tumor regression of a number of adjuvants that have been applied to immunotherapy in humans and tumor-bearing animal models has been tested without understanding of the function of adjuvants. Recent findings on the function of Toll-like receptors (TLRs) and their adaptors facilitated the elucidation of the molecular basis of adjuvant activity. TLR signaling was found to induce interferons (IFNs), chemokines and proinflammatory cytokines and mature dendritic cells (DCs) for enhanced efficiency in antigen presentation. The mediators then play a crucial role in the organization of acquired immunity and, together with matured DCs, activate cytotoxic T cells (CTL) and NK cells. These TLR outputs vary among adjuvants, which may depend on adjuvant-specific selection of appropriate sets of TLRs and their adaptors. Here we review how a variety of host immune responses are induced by an individual adjuvant to confer an adjuvant-specific anti-tumor immunity. We elaborate specifically on two adjuvants, BCG-cell wall skeleton and double-stranded RNA (dsRNA). The former activates TLR2/4 on DCs and induces tumor-specific CTL allowing general application to patients with surgically dissected cancer and improving prognosis, while the latter activates TLR3 on DCs to release type 1 IFN that induces tumor cell apoptosis and NK-mediated tumor cytotoxicity.

Silverstein, R. and D. C. Johnson (2003). "Endogenous versus exogenous glucocorticoid responses to experimental bacterial sepsis." J Leukoc Biol 73(4): 417-27.

            Although lack of adrenals dramatically reduces resistance against sepsis generally, the value of glucocorticoid levels above those normally produced by stress remains controversial. An early and long-held concept is that glucocorticoid protection against lipopolysaccharides in animal models is important. Supporting this concept, C3H/HeJ mice, lacking Toll-like receptor-4 (TLR-4), and consequently, endotoxin hyporesponsive, have recently been shown to be resistant to glucocorticoid protection against live Escherichia coli. Effective antibiotic intervention, as an additional parameter and with concomitant administration of glucocorticoid, not only allows for expected antibiotic protection but also for glucocorticoid protection against E. coli or Staphylococcus aureus of mice sensitized to tumor necrosis factor alpha, regardless of the status of the TLR-4 receptor. TLRs, including but not limited to TLR-2, may be involved in glucocorticoid protective efficacy against Gram-positive and Gram-negative sepsis. Overlapping and possibly endotoxin-independent signaling may become important considerations.

Someya, T., K. Sasaki, et al. (2003). "[The application of molecular biology to anti-endotoxin therapies]." Nippon Geka Gakkai Zasshi 104(7): 523-6.

            Toll-like receptors (TLRs), recently identified on macrophages and dendritic cells in mammals, recognize a specific pattern of pathogen components, including endotoxins(lipopolysaccharide). Pathogen recognition by TLRs activates the innate immune system through the signaling pathway and provokes inflammatory responses, such as inducing the production of cytokines. Therefore the specific inhibition of the signaling pathway and the administration of excess inflammatory responses have useful potential in the management of sepsis syndrome. Currently, several monoclonal antibodies are applicable to the treatment of autoimmune diseases and cancer. On the other hand, immunotherapies against proinflammatory cytokines in septic shock have failed to demonstrate clinical benefit. In this review, we summarize recent views of novel therapeutic targets, provided from molecular biologic studies of gram-negative infection.

Strieter, R. M., J. A. Belperio, et al. (2003). "Host innate defenses in the lung: the role of cytokines." Curr Opin Infect Dis 16(3): 193-8.

            PURPOSE OF REVIEW: The lung has a unique relationship with the environment. Through evolution the lung has developed strategies to defend itself from microbial invasion. As we encounter increasing multidrug-resistant microorganisms, we need to further our knowledge of innate defense systems in order to design novel strategies to deal with these microbes without inducing over-exuberant inflammation and lung injury. RECENT FINDINGS: The development of lung innate immunity requires microbial molecular pattern recognition by the recently described Toll like receptors, the release of early response cytokines that further activate the 'master switch', nuclear factor-kappaB, leading to amplified host defense to invading microbes. A balance of Type 1 and Type 2 cytokines modulates the intensity of innate immunity. Cytokines/chemokines orchestrate the polarization and transition of innate to adaptive immunity. SUMMARY: The elucidation of the pathways involved in innate immunity and factors controlling the transition to adaptive immunity will improve our understanding of the host response to infection and improve our ability to design new therapies for the treatment of infectious disease.

Sundquist, M., C. Johansson, et al. (2003). "Dendritic cells as inducers of antimicrobial immunity in vivo." Apmis 111(7-8): 715-24.

            Models of infection have provided important insight into the function of dendritic cells (DC) in vivo. Several microbial products induce DC maturation via Toll-like receptors, a process that is crucial for the ability of DC to initiate adaptive immune responses. Splenic DC have also been shown to produce IL-12 during infection in vivo. This DC-derived IL-12 might be important to skew T cell responses towards Th1. Microbial infections also induce changes in the DC populations of lymphoid organs, often in a subset-specific manner, manifested as an accumulation and redistribution of DC. Furthermore, data are emerging pointing at an absolute requirement of DC in priming of naive T cells in vivo.

Takahashi, H. (2003). "Antigen presentation in vaccine development." Comp Immunol Microbiol Infect Dis 26(5-6): 309-28.

            A variety of microorganisms, nutrients or toxins are generally intrude our body through mucosal tissues or skin, where equipment for both preventing their invasions and catching their information to activate internal immune systems for adapting surroundings is arranged. Among the equipment, cells in charge of innate immunity, particularly dendritic cells (DCs), having an excellent capacity for prompt recognition of invaded pathogens via toll-like receptors (TLRs) to alert B and T cells for establishing aquired/adaptive immunity by presenting their processed antigenic fragments, have been paid great attention. These TLR-activated, antigen captured DCs are divided into two groups; one is pathogen-retaining unit and the other is pathogen-controlling unit. The latter DCs present processed antigenic molecules from the pathogens to competent alphabeta T cells together with special containers, such as class I, class II MHC and CD1 to generate specific cellular immunity. The former two MHC molecules can present processed peptide antigens, whereas the last CD1 molecule can present glycolipid/lipid antigens. In contrast, B lymphocytes that captured antigens via their specific immunoglobulin (Ig) receptors present digested peptide fragments with their class II MHC to stimulate suitable CD4(+) helper T cells which in turn secrete various cytokines to efficiently expand and maintain antibody production from that partner B cells to establish humoral immunity. These alphabeta T cells and antibodies, recognize either processed antigenic peptide or glycolipid fragments, and thus, identification of these epitopes enables us to generate artificial pathogen-specific vaccines. Based on the recent findings about precise mechanisms of antigen processing and presentation orchestrated at the surface compartment, future development of vaccines against various pathogens are discussed.

Takeda, K. and S. Akira (2003). "Toll receptors and pathogen resistance." Cell Microbiol 5(3): 143-53.

            Toll receptors in insects, mammals and plants are key players that sense the invasion of pathogens. Toll-like receptors (TLRs) in mammals have been established to detect specific components of bacterial and fungal pathogens. Furthermore, recent evidence indicates that TLRs are involved in the recognition of viral invasion. Signalling pathways via TLRs originate from the conserved Toll/IL-1 receptor (TIR) domain. The TIR domain-containing MyD88 acts as a common adaptor that induces inflammatory cytokines; however, there exists a MyD88-independent pathway that induces type I IFNs in TLR4 and TLR3 signalling. Another TIR domain-containing adaptor, TIRAP/Mal has recently been shown to mediate the MyD88-dependent activation in the TLR4 and TLR2 signalling pathway. Thus, individual TLRs may have their own signalling systems that characterize their specific activities.

Takeda, K., T. Kaisho, et al. (2003). "Toll-like receptors." Annu Rev Immunol 21: 335-76.

            The innate immune system in drosophila and mammals senses the invasion of microorganisms using the family of Toll receptors, stimulation of which initiates a range of host defense mechanisms. In drosophila antimicrobial responses rely on two signaling pathways: the Toll pathway and the IMD pathway. In mammals there are at least 10 members of the Toll-like receptor (TLR) family that recognize specific components conserved among microorganisms. Activation of the TLRs leads not only to the induction of inflammatory responses but also to the development of antigen-specific adaptive immunity. The TLR-induced inflammatory response is dependent on a common signaling pathway that is mediated by the adaptor molecule MyD88. However, there is evidence for additional pathways that mediate TLR ligand-specific biological responses.

Trinchieri, G. (2003). "Interleukin-12 and the regulation of innate resistance and adaptive immunity." Nat Rev Immunol 3(2): 133-46.

            Interleukin-12 (IL-12) is a heterodimeric pro-inflammatory cytokine that induces the production of interferon-gamma (IFN-gamma), favours the differentiation of T helper 1 (T(H)1) cells and forms a link between innate resistance and adaptive immunity. Dendritic cells (DCs) and phagocytes produce IL-12 in response to pathogens during infection. Production of IL-12 is dependent on differential mechanisms of regulation of expression of the genes encoding IL-12, patterns of Toll-like receptor (TLR) expression and cross-regulation between the different DC subsets, involving cytokines such as IL-10 and type I IFN. Recent data, however, argue against an absolute requirement for IL-12 for T(H)1 responses. Our understanding of the relative roles of IL-12 and other factors in T(H)1-type maturation of both CD4+ and CD8+ T cells is discussed here, including the participation in this process of IL-23 and IL-27, two recently discovered members of the new family of heterodimeric cytokines.

Tschopp, J., F. Martinon, et al. (2003). "NALPs: a novel protein family involved in inflammation." Nat Rev Mol Cell Biol 4(2): 95-104.

            A newly discovered family of cytoplasmic proteins--the NALPs--has been implicated in the activation of caspase-1 by the Toll-like receptors (TLRs) during the cell's response to microbial infection. Like the structurally related apoptotic protease-activating factor-1 (APAF-1), which is responsible for the activation of caspase-9, the NALP1 protein forms a large, signal-induced multiprotein complex, the inflammasome, resulting in the activation of pro-inflammatory caspases.

Uhlmann, E. and J. Vollmer (2003). "Recent advances in the development of immunostimulatory oligonucleotides." Curr Opin Drug Discov Devel 6(2): 204-17.

            Some immune cells recognize distinct molecular structures present in pathogens through specific pattern recognition receptors that are able to distinguish prokaryotic DNA from vertebrate DNA. The detection of invading microbial DNA is based on the recognition of unmethylated deoxycytidyl-deoxyguanosin dinucleotide (CpG) motifs. Synthetic oligonucleotides (ODNs) containing these CpG motifs are able to activate both innate and acquired immune responses through a signaling pathway involving Toll-like receptor 9 (TLR9). Depending on the sequence, length, as well as number and positions of CpG motifs in an ODN, distinct immunostimulatory profiles can be observed. These immunostimulatory profiles can be further modified and fine-tuned by appropriate chemical modifications, leading to preclinical and clinical development of CpG ODNs in cancer, allergy, asthma and infectious diseases.

Underhill, D. M. (2003). "Toll-like receptors: networking for success." Eur J Immunol 33(7): 1767-75.

            The innate immune system is essential for host defense and is responsible for early detection of potentially pathogenic microorganisms. Upon recognition of microbes by innate immune cells such as macrophages and dendritic cells, diverse signaling pathways are activated that combine to define inflammatory responses that direct sterilization of the threat and/or orchestrate development of the adaptive immune response. Innate immune signaling must be carefully controlled, and regulation comes in part from interactions between activating and inhibiting signaling receptors. Toll-like receptors (TLR) have recently emerged as key receptors responsible for recognizing specific conserved components of microbes including lipopolysaccharides from Gram-negative bacteria, CpG DNA, and flagellin. Full activation of inflammatory responses by TLR may require the assembly of receptor signaling complexes including other transmembrane proteins that may influence signal transduction. In addition to TLR, many additional receptors participate in innate recognition of microbes, and recent studies demonstrate strong interactions between signaling through these receptors and signaling through TLR. Useful models for these interacting signaling pathways are now emerging and should pave the way for understanding the molecular mechanisms that drive the rich diversity of inflammatory responses.

Van Amersfoort, E. S., T. J. Van Berkel, et al. (2003). "Receptors, mediators, and mechanisms involved in bacterial sepsis and septic shock." Clin Microbiol Rev 16(3): 379-414.

            Bacterial sepsis and septic shock result from the overproduction of inflammatory mediators as a consequence of the interaction of the immune system with bacteria and bacterial wall constituents in the body. Bacterial cell wall constituents such as lipopolysaccharide, peptidoglycans, and lipoteichoic acid are particularly responsible for the deleterious effects of bacteria. These constituents interact in the body with a large number of proteins and receptors, and this interaction determines the eventual inflammatory effect of the compounds. Within the circulation bacterial constituents interact with proteins such as plasma lipoproteins and lipopolysaccharide binding protein. The interaction of the bacterial constituents with receptors on the surface of mononuclear cells is mainly responsible for the induction of proinflammatory mediators by the bacterial constituents. The role of individual receptors such as the toll-like receptors and CD14 in the induction of proinflammatory cytokines and adhesion molecules is discussed in detail. In addition, the roles of a number of other receptors that bind bacterial compounds such as scavenger receptors and their modulating role in inflammation are described. Finally, the therapies for the treatment of bacterial sepsis and septic shock are discussed in relation to the action of the aforementioned receptors and proteins.

van Eden, W., A. Koets, et al. (2003). "Immunopotentiating heat shock proteins: negotiators between innate danger and control of autoimmunity." Vaccine 21(9-10): 897-901.

            Heat shock proteins (hsps) are known to be immunodominant antigens of bacteria. Hsps are evolutionarily strongly conserved proteins present in all eukaryotic and prokaryotic cellular organisms and upregulated by several forms of stress. Despite (the paradigm of) self-tolerance, hsp-epitopes homologous to endogenous host hsp sequences have been implicated as T cell epitopes to endow crossreactive, hsp-specific T cells with the capacity to regulate inflammation, such as in experimentally induced autoimmune diseases. Such T cells were found to produce regulatory cytokines like IL10, in contrast to T cells induced with other conserved microbial proteins that are not upregulated by stress. Hsps have been implicated in immune regulation not only as upregulated targets of adaptive immunity during inflammatory stress, but recently also as triggering factors for innate immunity through activation via Toll-like receptors (TLRs).

van Kooyk, Y. and T. B. Geijtenbeek (2003). "DC-SIGN: escape mechanism for pathogens." Nat Rev Immunol 3(9): 697-709.

            Dendritic cells (DCs) are crucial in the defence against pathogens. Invading pathogens are recognized by Toll-like receptors (TLRs) and receptors such as C-type lectins expressed on the surface of DCs. However, it is becoming evident that some pathogens, including viruses, such as HIV-1, and non-viral pathogens, such as Mycobacterium tuberculosis, subvert DC functions to escape immune surveillance by targeting the C-type lectin DC-SIGN (DC-specific intercellular adhesion molecule-grabbing nonintegrin). Notably, these pathogens misuse DC-SIGN by distinct mechanisms that either circumvent antigen processing or alter TLR-mediated signalling, skewing T-cell responses. This implies that adaptation of pathogens to target DC-SIGN might support pathogen survival.

Werling, D. and T. W. Jungi (2003). "TOLL-like receptors linking innate and adaptive immune response." Vet Immunol Immunopathol 91(1): 1-12.

            Invading pathogens are controlled by the innate and adaptive arms of the immune system. Adaptive immunity, which is mediated by B and T lymphocytes, recognises pathogens by rearranged high affinity receptors. However, the establishment of adaptive immunity is often not rapid enough to eradicate microorganisms as it involves cell proliferation, gene activation and protein synthesis. More rapid defense mechanisms are provided by innate immunity, which recognises invading pathogens by germ-line-encoded pattern recognition receptors (PRR). Recent evidence shows that this recognition can mainly be attributed to the family of TOLL-like receptors (TLR). Binding of pathogen-associated molecular patterns (PAMP) to TLR induces the production of reactive oxygen and nitrogen intermediates (ROI and RNI), pro-inflammatory cytokines, and up-regulates expression of co-stimulatory molecules, subsequently initiating the adaptive immunity. In this review, we will summarize the discovery and the critical roles of the TLR family in host defense, briefly allude to signaling mechanisms mediating the response to TLR ligands, and will provide an update on current knowledge regarding the ligand specificity of these receptors and their role in immunity of domestic animals, particularly cattle.

Back to Top