ABO blood group and secretor status in the spondyloarthropathies

Abstract The postulated role of infectious agents, genetic susceptibility of the host to infection and their interaction in the pathogenesis of ankylosing spondylitis, other spondyloarthropathies, and the associated primary (non-arthritic) diseases are reviewed.
Compared with a local control population there is a significantly increased prevalence of non-secretors amongst different groups of patients with spondyloarthropathy: ankylosing spondylitis, reactive arthritis and psoriatic arthropathy. No differences between secretor and non-secretor patients with respect to serum and salivary IgA levels, the occurrence of eye lesions or peripheral joint disease have been found. There is no evidence that ankylosing spondylitis or other spondyloarthropathies are associated with any particular ABO blood group.
The association between non-secretion and ankylosing spondylitis strengthens the hypothesis that ankylosing spondylitis has an infective aetiology. It also suggests several pathogenetic mechanisms which may be relevant to the initial host-parasite interactions in the spondyloarthropathies.     

ABO blood group and secretor status in the spondyloarthropathies

The postulated role of infectious agents, genetic susceptibility of the host to infection and their interaction in the pathogenesis of ankylosing spondylitis, other spondyloarthropathies, and the associated primary (non-arthritic) diseases are reviewed. Compared with a local control population there is a significantly increased prevalence of non-secretors amongst different groups of patients with spondyloarthropathy: ankylosing spondylitis, reactive arthritis and psoriatic arthropathy. No differences between secretor and non-secretor patients with respect to serum and salivary IgA levels, the occurrence of eye lesions or peripheral joint disease have been found. There is no evidence that ankylosing spondylitis or other spondyloarthropathies are associated with any particular ABO blood group. The association between non-secretion and ankylosing spondylitis strengthens the hypothesis that ankylosing spondylitis has an infective aetiology. It also suggests several pathogenetic mechanisms which may be relevant to the initial host-parasite interactions in the spondyloarthropathies.     

The role of ABO blood groups and secretor status in host defences

Abstract Epidemiological studies on the associations between ABO blood group antigens, secretor status and susceptibility to infectious agents are summarized. Evidence for association of non-secretion with some autoimmune diseases for which infectious aetiologies have been proposed is also given. Several hypothesis are proposed to explain the host-parasite interactions underlying the epidemiological observations, and evidence to support or refute them is presented.     

The role of ABO blood groups and secretor status in host defences

Epidemiological studies on the associations between ABO blood group antigens, secretor status and susceptibility to infectious agents are summarized. Evidence for association of non-secretion with some autoimmune diseases for which infectious aetiologies have been proposed is also given. Several hypotheses are proposed to explain the host-parasite interactions underlying the epidemiological observations, and evidence to support or refute them is presented.     

Cationic amino acid transporter 2 enhances innate immunity during Helicobacter pylori infection

Once acquired, Helicobacter pylori infection is lifelong due to an inadequate innate and adaptive immune response. Our previous studies indicate that interactions among the various pathways of arginine metabolism in the host are critical determinants of outcomes following infection. Cationic amino acid transporter 2 (CAT2) is essential for transport of L-arginine (L-Arg) into monocytic immune cells during H. pylori infection. Once within the cell, this amino acid is utilized by opposing pathways that lead to elaboration of either bactericidal nitric oxide (NO) produced from inducible NO synthase (iNOS), or hydrogen peroxide, which causes macrophage apoptosis, via arginase and the polyamine pathway. Because of its central role in controlling L-Arg availability in macrophages, we investigated the importance of CAT2 in vivo during H. pylori infection. CAT2(-/-) mice infected for 4 months exhibited decreased gastritis and increased levels of colonization compared to wild type mice. We observed suppression of gastric macrophage levels, macrophage expression of iNOS, dendritic cell activation, and expression of granulocyte-colony stimulating factor in CAT2(-/-) mice suggesting that CAT2 is involved in enhancing the innate immune response. In addition, cytokine expression in CAT2(-/-) mice was altered from an antimicrobial Th1 response to a Th2 response, indicating that the transporter has downstream effects on adaptive immunity as well. These findings demonstrate that CAT2 is an important regulator of the immune response during H. pylori infection.     

Role of interleukin-13 in innate and adaptive immunity.

Initially thought to be functionally redundant with IL-4 as a predominant anti-inflammatory factor secreted during type-2 T-cell responses, IL-13 possesses a number of additional properties that distinguish it from IL-4 in addition to having both anti-inflammatory and immune activating properties. This review centers primarily on the role of IL-13 in the regulation of cellular functions of innate immunity and acquired immunity against certain microbial pathogens. First, we discuss IL-13's regulation of innate cell targets and its impact on inflammation, antigen uptake and antigen presentation. Second, we focus on IL-13's involvement in acquired immunity to infectious helminths and protozoa. The role of this cytokine in immune responses is still being determined but evidence to date suggests this molecule has been conserved as an important regulatory factor involved in both early innate and late adaptive responses.     

Control of mucosal polymicrobial populations by innate immunity

The gastrointestinal tract carries out the complex process of localizing the polymicrobial populations of the indigenous microbiota to the lumenal side of the GI mucosa while absorbing nutrients from the lumen and preventing damage to the mucosa. This process is accomplished through a combination of physical, innate and adaptive host defences and a 'strategic alliance' with members of the microbiota. To cope with the constant exposure to a diverse microbial community, the GI tract, through the actions of a number of specialized cells in the epithelium and lamina propria, has layers of humoral, physical and cellular defences that limit attachment, invasion and dissemination of the indigenous microbiota. However, the role of the microbiota in this dynamic balance is vital and serves as another level of 'innate' defence. We are just beginning to understand how bacterial metabolites aid in the control of potential pathogens within the microbiota and limit inflammatory responses to the microbiota, concepts that will impact our understanding of the biological effects of antibiotics, diet and probiotics on mucosal inflammatory responses.     

Intestinal epithelial cells and their role in innate mucosal immunity

The mucosal surfaces of the respiratory, gastrointestinal and urogenital tracts are covered by a layer of epithelial cells that are responsible for sensing and promoting a host immune response in order to establish the limits not only for commensal microorganisms but also for foreign organisms or particles. This is a remarkable task as the human body represents a composite of about 10 trillion human-self cells plus non-self cells from autochthonous or indigenous microbes that outnumber human cells 10:1. Hence, the homeostasis of epithelial cells that line mucosal surfaces relies on a fine-tuned immune system that patrols the boundaries between human and microbial cells. In the case of the intestine, the epithelial layer is composed of at least six epithelial cell lineages that act as a physiological barrier in addition to aiding digestion and the absorption of nutrients, water and electrolytes. In this review, we highlight the immense role of the intestinal epithelium in coordinating the mucosal innate immune response.     

Sequence of action of genes at the secretor, H, ABO and Lewis loci.

It is argued that Lewis genes are responsible for adding specificity to glycoprotein molecules after the activities of the secretor, H and ABO genes, respectively, have been expressed. This conclusion is based on the results of studies on the expression of ABO and Lewis antigens in salivas from Australian aborigines, and on biochemical results. A simple figure illustrating the antigens determined on red cells and in body secretions as a result of the action of these genes, in their correct order--secretor, H, ABO, Lewis--is presented.     

模式识别受体Dectin-1与天然免疫反应

在免疫反应早期,抗原递呈细胞表达的模式识别受体通过识别内、外源配体在清除衰老宿主细胞、分子以及防御感染中发挥重要作用。新近发现的树突状细胞相关性C型植物血凝素-1(dendritic cell—associated C-type lectin-1,Dectin-1)作为β-葡聚糖的主要受体,广泛分布于单核巨噬细胞系统、树突状细胞(dendritic cell,DC)及中性粒细胞等。本文对Dectin-1分子结构、细胞组织分布及其在诱导、调控局部和全身免疫、炎症反应中的作用进行概述。     

ABO blood group,secretor state,and susceptibility to recurrent urinary tract infection in women.

ABO blood group and secretor state was determined in 319 women with recurrent urinary tract infection and compared with those of a control group of 334 women of similar age ranges. Women of blood groups B and AB who are non-secretors of blood group substances showed a significant relative risk of recurrent urinary tract infection of 3.12 (95% confidence limits, 1.49 and 6.52) in comparison with other types. This appears to be a genuine example of synergy in which absence of anti-B isohaemagglutinin and secretor substances combines to give an increased risk of recurrent urinary tract infection. Determination of blood group and secretor state may provide additional information in identifying those at risk.     

Antimicrobial peptides and proteins, exercise and innate mucosal immunity

This review examines the question of whether exercise can be used as an experimental model to further our understanding of innate antimicrobial peptides and proteins (AMPs) and their role in susceptibility to infection at mucosal surfaces. There is strong evidence to suggest that AMPs, in combination with cellular and physical factors, play an important role in preventing infection. Although AMPs act directly on microorganisms, there is increasing recognition that they also exert their protective effect via immunomodulatory mechanisms, especially in noninflammatory conditions. Further studies that manipulate physiologically relevant concentrations of AMPs are required to shed light on the role they play in reducing susceptibility to infection. Evidence shows that in various form prolonged and/or exhaustive exercise is a potent modulator of the immune system, which can either sharpen or blunt the immune response to pathogens. The intensity and duration of exercise can be readily controlled in experimental settings to manipulate the degree of physical stress. This would allow for an investigation into a potential dose-response effect between exercise and AMPs. In addition, the use of controlled exercise could provide an experimental model by which to examine whether changes in the concentration of AMPs alters susceptibility to illness.     

H. pylori exploits and manipulates innate and adaptive immune cell signaling pathways to establish persistent infection

Persistent infection with the gastric bacterial pathogen Helicobacter pylori causes gastritis and predisposes carriers to a high gastric cancer risk, but has also been linked to protection from allergic, chronic inflammatory and autoimmune diseases. In the course of tens of thousands of years of co-existence with its human host, H. pylori has evolved elaborate adaptations that allow it to persist in the hostile environment of the stomach in the face of a vigorous innate and adaptive immune response. For this review, we have identified several key immune cell types and signaling pathways that appear to be preferentially targeted by the bacteria to establish and maintain persistent infection. We explore the mechanisms that allow the bacteria to avoid detection by innate immune cells via their pattern recognition receptors, to escape T-cell mediated adaptive immunity, and to reprogram the immune system towards tolerance rather than immunity. The implications of the immunomodulatory properties of the bacteria for the prevention of allergic and auto-immune diseases in chronically infected individuals are also discussed.     

Role of chemokines,innate and adaptive immunity

Polycystic Kidney Disease (PKD) triggers a robust immune system response including changes in both innate and adaptive immunity. These changes involve immune cells (e.g., macrophages and T cells) as well as cytokines and chemokines (e.g., MCP-1) that regulate the production, differentiation, homing, and various functions of these cells. This review is focused on the role of the immune system and its associated factors in the pathogenesis of PKDs as evidenced by data from cell-based systems, animal models, and PKD patients. It also highlights relevant pre-clinical and clinical studies that point to specific immune system components as promising candidates for the development of prognostic biomarkers and therapeutic strategies to improve PKD outcomes.     

MicroRNA in innate immunity and autophagy during mycobacterial infection

The fine‐tuning of innate immune responses is an important aspect of host defenses against mycobacteria. MicroRNAs (miRNAs), small non‐coding RNAs, play essential roles in regulating multiple biological pathways including innate host defenses against various infections. Accumulating evidence shows that many miRNAs regulate the complex interplay between mycobacterial survival strategies and host innate immune pathways. Recent studies have contributed to understanding the role of miRNAs, the levels of which can be modulated by mycobacterial infection, in tuning host autophagy to control bacterial survival and innate effector function. Despite considerable efforts devoted to miRNA profiling over the past decade, further work is needed to improve the selection of appropriate biomarkers for tuberculosis. Understanding the roles and mechanisms of miRNAs in regulating innate immune signaling and autophagy may provide insights into new therapeutic modalities for host‐directed anti‐mycobacterial therapies. Here, we present a comprehensive review of the recent literature regarding miRNA profiling in tuberculosis and the roles of miRNAs in modulating innate immune responses and autophagy defenses against mycobacterial infections.