Antitumour immune responses

The role of the immune system in combating tumour progression has been studied extensively. The two branches of the immune response - humoral and cell-mediated - act both independently and in concert to combat tumour progression, the success of which depends on the immunogenicity of the tumour cells. The immune system discriminates between transformed cells and normal cells by virtue of the presence of unique antigens on tumour cells. Despite this, the immune system is not always able to detect and kill cancerous cells because neoplasms have also evolved various strategies to escape immune surveillance. Attempts are being made to trigger the immune system into an early and efficient response against malignant cells, and various therapeutic modalities are being developed to enhance the strength of the immune response against tumours. This review aims to elucidate the tumoricidal role of various components of the immune system, including macrophages, lymphocytes, dendritic cells and complement.     

Neural immune pathways and their connection to inflammatory diseases

Inflammation and inflammatory responses are modulated by a bidirectional communication between the neuroendocrine and immune system. Many lines of research have established the numerous routes by which the immune system and the central nervous system (CNS) communicate. The CNS signals the immune system through hormonal pathways, including the hypothalamic-pituitary-adrenal axis and the hormones of the neuroendocrine stress response, and through neuronal pathways, including the autonomic nervous system. The hypothalamic-pituitary-gonadal axis and sex hormones also have an important immunoregulatory role. The immune system signals the CNS through immune mediators and cytokines that can cross the blood-brain barrier, or signal indirectly through the vagus nerve or second messengers. Neuroendocrine regulation of immune function is essential for survival during stress or infection and to modulate immune responses in inflammatory disease. This review discusses neuroimmune interactions and evidence for the role of such neural immune regulation of inflammation, rather than a discussion of the individual inflammatory mediators, in rheumatoid arthritis.     

Viral immune evasion: a masterpiece of evolution

Coexistence of viruses and their hosts imposes an evolutionary pressure on both the virus and the host immune system. On the one hand, the host has developed an immune system able to attack viruses and virally infected cells, whereas on the other hand, viruses have developed an array of immune evasion mechanisms to escape killing by the host's immune system. Generally, the larger the viral genome, the more diverse mechanisms are utilized to extend the time-window for viral replication and spreading of virus particles. In addition, herpesviruses have the capacity to hide from the immune system by their ability to establish latency. The strategies of immune evasion are directed towards three divisions of the immune system, i.e., the humoral immune response, the cellular immune response and immune effector functions. Members of the herpesvirus family are capable of interfering with the host's immune system at almost every level of immune clearance. Antibody recognition of viral epitopes, presentation of viral peptides by major histocompatibility complex (MHC) class I and class II molecules, the recruitment of immune effector cells, complement activation, and apoptosis can all be impaired by herpesviruses. This review aims at summarizing the current knowledge of viral evasion mechanisms.     

Immune system physiology

Processes of interaction of immunocytes of different origin and with different cytokins, underlie the immune system mechanisms. The immune system structure, lymphocytes variety and properties, molecular basis of antigen recognition, were described. Dynamic structure of peripheral part of the immune system, immunocytes migration and re-circulation role in integration of lymphoid organs, were demonstrated. The molecular and cellular basis of the immune reaction and immune memory, were discussed.     

肝脏固有免疫系统对肠源性感染的免疫应答与免疫耐受机制

肝特殊的解剖结构及生理特征使其成为暴露肠源性抗原的主要器官。由于肝具有独特的固有免疫系统,在正常情况下,肝分布多种致耐受的抗原提呈细胞,对持续性表达或递呈于肝的肠源性抗原物质,诱发针对该抗原的系统性免疫耐受,避免肝受到不必要的免疫损伤。当炎症发生及肝脏固有免疫系统活化时,则通过免疫效应细胞及免疫效应因子对肠源性病原体发挥强烈地免疫应答以控制感染。该过程形成机制的研究对肝功能的理解及肝性疾病的预防与治疗至关重要。本文就肝固有免疫系统对肠源性感染的免疫应答与免疫耐受形成机制作一综述。     

免疫细胞衰老表现及免疫功能变化的研究进展

机体衰老的本质是细胞衰老不断累积的过程。免疫系统的衰老既是机体衰老的必然结果,也是导致机体衰老的重要原因。免疫系统作为衰老变化的主要系统之一受到越来越多的学者重视。本文将从适应性免疫系统的T、B细胞及固有免疫系统的自然杀伤(NK)细胞、巨噬细胞、中性粒细胞、树突状细胞(DC)和骨髓源性抑制细胞等免疫细胞的亚群、衰老指标和功能等方面在衰老过程中的改变进行总结,进一步明确免疫系统衰老在机体衰老过程中扮演的重要角色。     

Do endogenous cannabinoids contribute to HIV-mediated immune failure?

The failure of the immune system to mount a successful attack on the human immunodeficiency virus (HIV) is an old enigma for AIDS research. The high mutational capacity of HIV, which unremittingly confuses the immune system, is a major factor in immune failure. But this alone cannot fully explain the certain and inescapable failure of the immune system, leading to full-blown AIDS. Here, we propose the hypothesis that endogenous cannabinoids, derived mostly from macrophages, might participate in the general failure of the immune system in HIV-infected individuals.     

Toll信号通路在中枢神经系统损伤中的作用

Toll样受体(Toll-like receptors,TLR)是先天性免疫反应识别病原体的一个重要分子,在免疫系统中发挥关键作用.其家族各种成员的主要功能是识别入侵病原体表面的各种不同分子模式,随后启动免疫反应,达到保护机体作用.在大脑中,小胶质细胞可以作为抗原提呈细胞,参与脑内免疫反应,也可以通过分泌各种促炎症因子启动或促进免疫反应,而TLR家族在中枢神经免疫系统的作用仍存在争议,它既可以通过促进神经免疫反应枢纽因子的表达来增强免疫,也可因免疫过度而损伤神经细胞.总之,Toll信号通路对中枢神经系统疾病有一定的调控作用.     

Immunological Control of Fish Diseases

All metazoans possess innate immune defence system whereas parameters of the adaptive immune system make their first appearance in the gnathostomata, the jawed vertebrates. Fish are therefore the first animal phyla to possess both an innate and adaptive immune system making them very interesting as regards developmental studies of the immune system. The massive increase in aquaculture in recent decades has also put greater emphasis on studies of the fish immune system and defence against diseases commonly associated with intensive fish rearing. Some of the main components of the innate and adaptive immune system of fish are described. The innate parameters are at the forefront of immune defence in fish and are a crucial factor in disease resistance. The adaptive response of fish is commonly delayed but is essential for lasting immunity and a key factor in successful vaccination. Some of the inherent and external factors that can manipulate the immune system of fish are discussed, the main fish diseases are listed and the pathogenicity and host defence discussed. The main prophylactic measures are covered, including vaccination, probiotics and immunostimulation. A key element in the immunological control of fish diseases is the great variation in disease susceptibility and immune defence of different fish species, a reflection of the extended time the present day teleosts have been separated in evolution. Future research will probably make use of molecular and proteomic tools both to study important elements in immune defence and prophylactic measures and to assist with breeding programmes for disease resistance.     

Modelling Immune System: Principles, Models,Analysis and Perspectives

The biological immune system is a complex adaptive system.There are lots of benefits for building the model of theimmune system.For biological researchers,they can test some hypotheses about the infection process or simulate the responsesof some drugs.For computer researchers,they can build distributed,robust and fault tolerant networks inspired by the functionsof the immune system.This paper provides a comprehensive survey of the literatures on modelling the immune system.Fromthe methodology perspective,the paper compares and analyzes the existing approaches and models,and also demonstrates thefocusing research effort on the future immune models in the next few years.     

Screening of xenobiotics for direct immunotoxicity in an animal study

It has now been recognised that the immune system as a whole can be the target for xenobiotic induced toxicity. The discipline of immuntoxicology encompasses non specific direct immunotoxicity and immunostimulation, and specific responses like hypersensitivity and autoimmunity. Direct immunotoxicity can be determined in tiered studies, TIER 1 being a general toxicity study with emphasis on evaluation of organs belonging to the immune system, TIER 2 investigating the effects of xenobiotics on immune functionality in immunological challenge experiments. In the TIER 1 study, organ weights and histopathological evaluation of immune organs like spleen, thymus, lymph nodes, blood and bone marrow may detect the occurrence of direct immunotoxicity. The follow up studies in the TIER 2 phase can then determine the extent of the immunosuppression and identify which specific parts or cellular components of the immune system are involved. In view of the complexity of the immune system and the multitude of interactions within the immune system in vivo animal experiments are needed to investigate xenobiotics for their potential immunotoxicity. In vitro assays with in vivo exposed cells of the immune system may present additional information on the mechanisms involved in the observed direct immunotoxicity.     

A formal model of an artificial immune system

The paper presents a mathematical model based on the features of antigen-antibody bindings in the immune system. In the natural immune system, local binding of immune cells and molecules to antigenic peptides is based generally on the behavior of surface proteins. In particular, immune cells contain proteins on their receptors, and apparently, these proteins play the key role both in immune response and recognition processes. In this work, we consider the immune cells in the form of formal B-cell and formal T-cell and develop a mathematical model of their interactions. We refer this model as the formal immune system (FIS). The paper provides an analysis of a network of bindings (or interactions) among the formal proteins of the FIS.     

抗病毒天然免疫研究

病毒是一种极具感染性和传染性的病原微生物．当病毒感染机体以后,机体会通过激活免疫系统来进行防御．高等哺乳动物的免疫系统分为两大类：适应性免疫系统和天然免疫系统．适应性免疫系统主要通过T淋巴细胞和B淋巴细胞特异性地识别入侵的病毒并将其清除．而天然免疫系统主要通过模式识别受体识别病毒的入侵,进而产生一系列的细胞因子抵抗病毒的入侵．其中,天然免疫系统作为抵御病毒入侵的第一道防线和激活后续适应性免疫的先决条件在整个抗病毒免疫反应中发挥着十分重要的作用．     

Scale-free dynamics of somatic adaptability in immune system

The long-time dynamics of somatic adaptability in immune system is simulated by a simple physical model defined in the shape space. The immune system described by the model exhibits a scale free behavior as is observed in living systems. The balance between the positive and negative feedbacks of the model leads to a robust immune system where the positive one corresponds to the formation of memory cells and the negative one to immunosuppression. Also the immunosenescence of the system is discussed based on the time-dependence of the epigenetic landscape of the adaptive immune cells in the shape space.     

Neural and Pavlovian influences on immunity

The traditional view that the nervous and immune systems are functionally independent (aside from general stress effects and autoimmune disorders of the nervous system) is being challenged by a new view that the nervous system regulates the activity of the immune system. If this is true, it should be possible to change the activity of the immune system by means of Pavlovian conditioning, just as it is possible to condition other physiological events influenced by the autonomic nervous system or neuroendocrine substances. Evidence for autonomic and neuroendocrine modulation of immune activity is briefly reviewed; and, the various studies reporting conditioned immune effects, the physiological mechanisms most likely involved, and their possible significance are discussed.     

螺旋藻保健功能的研究(Ⅰ)——免疫调节保健功能的检验与评价

本研究对螺旋藻产品的免疫调节保健功能进行了检验和评价。小鼠实验结果显示 ,饲喂螺旋藻可以增强其体液免疫、细胞免疫、自然杀伤细胞和巨噬细胞等免疫系统的重要组成部分的活力。研究表明 ,螺旋藻能协调地改善免疫系统的功能 ,它不愧是优秀的保健食品。     

基于细胞自动机的实体肿瘤生长动态建模

基于细胞自动机方法,建立了一种简单的实体肿瘤免疫性系统模型,用来模拟实体肿瘤生长过程中的情况．我们基于二维随机、离散细胞自动机计算方法,在生物细胞水平上,建立了一种肿瘤免疫性系统生长模型．该模型考虑了免疫反应的宏观性质,描绘了癌细胞和机体免疫系统之间的细胞相互作用,表现了围绕在肿瘤机体周围,免疫系统细胞的免疫作用发展情况．我们研究了常规细胞自动机模型,设计出实体肿瘤模型随机演化生长规则．最终,构建离散细胞自动机肿瘤免疫性系统模型,并做了相应的数值仿真试验．通过对仿真模型不同参数的调整,最终的仿真结果表明,该模型能反映肿瘤免疫性系统基本的相关性质．     

The stress response and immune system share,borrow, and reconfigure their physiological network elements: Evidence from the insects

The classic biomedical view is that stress hormone effects on the immune system are largely pathological, especially if the stress is chronic. However, more recent interpretations have focused on the potential adaptive function of these effects. This paper examines stress response-immune system interactions from a physiological network perspective, using insects because of their simpler physiology. For example, stress hormones can reduce disease resistance, yet activating an immune response results in the release of stress hormones in both vertebrates and invertebrates. From a network perspective, this phenomenon is consistent with the ‘sharing’ of the energy-releasing ability of stress hormones by both the stress response and the immune system. Stress-induced immunosuppression is consistent with the stress response ‘borrowing’ molecular components from the immune system to increase the capacity of stress-relevant physiological processes (i.e. a trade off). The insect stress hormones octopamine and adipokinetic hormone can also ‘reconfigure’ the immune system to help compensate for the loss of some of the immune system's molecular resources (e.g. apolipophorin III). This view helps explain seemingly maladaptive interactions between the stress response and immune system. The adaptiveness of stress hormone effects on individual immune components may be apparent only from the perspective of the whole organism. These broad principles will apply to both vertebrates and invertebrates.     

Rapid evolution of immunoglobulin superfamily C2 domains expressed in immune system cells

To test the hypothesis that proteins expressed in cells of the vertebrate immune system evolve unusually rapidly, 107 orthologous immunoglobulin C2 domains were compared between human and murine rodent. The analysis showed that the rate of nonsynonymous (amino-acid- altering) nucleotide substitution in these domains was correlated with factors associated with protein structure and with breadth of tissue expression, as well as with the rate of synonymous substitution. However, when such factors were controlled for statistically, there remained a strong positive association between expression in the immune system and nonsynonymous rate, with the highest rates being seen in genes expressed in the immune system only. Certain immune system genes are known to be subject to positive selection favoring diversity at the amino acid level; most of these genes encode receptors that interact directly with foreign antigens. The observed acceleration of the rate of nonsynonymous evolution in C2 domains of immune system proteins may be explained by either (1) reduced constraint at the amino acid level on molecules interacting with immune system receptors that are themselves evolving rapidly due to positive diversifying selection or (2) positive selection favoring amino acid changes correlated with changes in the immune system receptors.      

Significance of the functional activity of toll-like receptors and other receptors of the innate immune system of the kidney physiology

The kidney needs to defend against microbial pathogens in order to maintain normal structure and function. This is achieved through innate and adaptive components of the immune system. For a long time, immunologists were concentrating on the adaptive immune system, which, as a result, was studied in detail; at the same time, the significance of the innate immune system was underestimated. This gap was partly filled in the recently, when the key role of the innate immune system in fighting microorganisms and in activating and regulating the adaptive immune system was convincingly established. In the first part of the present article, the sense apparatus of the innate immune system (the so-called pattern-recognition receptors) will be reviewed; particular attention will be paid to the toll-like receptors (TLRs), which bear the main burden of microorganism recognition. Signalling pathways that are activated by TLRs and result in the activation of effector mechanisms will also be reviewed. In the second part of the review, we will analyse available data on how these mechanisms of the innate immune system secure defence and normal functioning of the kidney.