Immune defense and suppression in insects

Insect endoparasitoids are able to circumvent the defense reactions of their habitual hosts. In a hymenopteran wasp species, virus-like particles, found on the egg surface are responsible for the protection against the encapsulation reaction of the host caterpillar. Some of the particle proteins are structurally and probably functionally related to host protein(s). Biological properties of some of the host proteins suggest that they might be involved in the insect defense reaction.     

Immune response inhibits associative learning in insects

In vertebrates, it is well established that there are many intricate interactions between the immune system and the nervous system, and vice versa. Regarding insects, until now little has been known about the link between these two systems. Here, we present behavioural evidence indicating a link between the immune system and the nervous system in insects. We show that otherwise non-infected honeybees whose immune systems are challenged by a non-pathogenic immunogenic elicitor lipopolysaccharide (LPS) have reduced abilities to associate an odour with sugar reward in a classical conditioning paradigm. The cost of an immune response therefore not only affects survival of the host, as previously shown, but also everyday behaviour and memory formation.     

Immune responses and parasite transmission in blood-feeding insects

The detailed model of insect immunity being built for Drosophila, allied to mass sequencing programs for blood-feeding insects, has led to advances in our understanding of the interaction between pathogens and insect vectors. An outline of insect immunity is given here based on the Drosophila studies, which is used as a framework to discuss recent work on Plasmodium-mosquito and Trypanosoma-tsetse interactions.     

昆虫味觉感受机制研究进展

很多昆虫具有极其灵敏的味觉感受系统, 在其取食选择、 交配和产卵等过程中起重要作用。相对于昆虫的嗅觉机制, 对昆虫味觉感受机制的研究较少。传统的味觉感受研究主要集中在味觉感器外部形态、 味觉电生理和行为学上。近年来随着分子遗传学、 生物信息学和神经生物学技术的应用, 昆虫味觉的研究不断深入, 主要体现在下列两方面： （1）味觉受体方面, 通过分子生物信息学等手段获得了多种昆虫的味觉受体, 不同种昆虫之间受体数目差异较大, 不同受体之间氨基酸的相似性较低。通常, 根据味觉受体配体物质的性质可以把味觉受体分为取食抑制素受体和取食刺激素受体两大类。（2）味觉神经元的投射及味觉编码机制方面, 多个研究表明昆虫外围味觉神经元在中枢神经系统中的投射部位为咽下神经节和后脑, 但是不同性质的受体神经元投射的具体位置有所不同。本文对昆虫味觉感器和神经元的基本特征, 味觉受体的进化、 表达和功能, 味觉神经元在中枢神经系统中的投射, 味觉神经元的编码机制及味觉可塑性等进行了综述。     

Immune mechanisms in trematode-snail interactions

Digenetic trematodes, including several species of medical and veterinary significance, nearly all depend on molluscs (usually gastropods) as hosts for asexual reproduction. The molluscan internal defence system, although lacking many of the familiar features of the vertebrate immune system, may pose a substantial obstacle to digenean development. In this article, Wil van der Knaap and Eric Loker discuss the manner in which this system is mobilized to kill larval trematodes and the real and putative mechanisms of digenean evasion of molluscan immune responses. These two possible outcomes of trematode-snail associations make them intriguing model systems for exploring processes of parasite infectivity and host resistance.     

Immune mechanisms in pain control

Pain inhibition can be induced by immune‐derived opioids interacting with opioid receptors on peripheral sensory nerves. These receptors are up‐regulated in inflammation (1). Opioid peptides are synthesised in circulating immune cells which migrate to injured tissue. This is orchestrated by selectins and other adhesion molecules located on immunocytes and on vascular endothelium (2). In response to releasing stimuli the opioids are secreted, activate peripheral opioid receptors and produce analgesia by inhibiting the excitability of sensory nerves and/or the release of excitatory neuropeptides. These effects occur in the periphery and are devoid of central side‐effects such as respiratory depression, sedation, dysphoria or dependence. Targeting of immune cells containing opioids to injured tissues is a novel concept of pain control and opens potential new therapeutic approaches.     

周期性羽化昆虫形成机制

当昆虫类群表现为长生命周期k(k > 1)年时,成虫的羽化表现为非周期性、周期性和过渡周期性3种形式。非周期性即为成虫每年均羽化,周期性即为成虫每k年才羽化1次,过渡周期性为非周期昆虫逐渐进化为羽化周期性的必经阶段,不同年份羽化的同生群在密度上产生了显著差异,形成了小同生群和优势同生群。自然界中表现出完全羽化周期性的昆虫种类是较少的,但由于其高种群密度的成虫同步性羽化现象,对比非周期性昆虫更易暴发成灾。为明确周期性昆虫演化进程并为林区虫害防控提供理论指导,总结了周期性昆虫的种类和生活特性,不同年间的气候异质性、自然灾害、扩散到未分布区域、天敌、种间和种内竞争等因素均有可能成为过渡周期现象形成的最初驱动力,生活史延长、寄主-天敌互作、低温驱动效应、天敌不敏感-捕食者饱足效应、种间和种内竞争等是促使昆虫羽化周期性形成的可能机制。在林区管理实践中,应提前评估害虫羽化周期性产生的趋势和程度。当成虫表现出完全羽化周期性,应在集中羽化年份内采取见效快的综合防控策略,降低唯一同生群密度至经济阈值以下。当成虫表现出过渡周期性,应加大优势同生群防治力度、降低小同生群防治频率,以及采取天敌林间释放和保育技术以平衡天敌对目标害虫的不同发育阶段种群的控制作用大小,遏制或减缓天敌-寄主互作驱动下的周期性演化进程,逐渐实现由过渡周期阶段向非周期性的逆转。当成虫表现出非周期性,应减少专化性天敌的释放和针对害虫特定阶段的防治措施使用频率,优先选择作用于所有发育阶段且致死率不存在显著差异的防治手段,避免因人为干扰产生的周期性演化和进一步的成灾。     

吸血昆虫生殖调控的分子机制

吸血昆虫是可以传播病原微生物的一类节肢动物,包括蚊虫、白蛉、蠓、猎蝽、跳蚤等。由于其特殊的吸血习性,它们成为了疟疾、登革热、丝虫病、锥虫病等急性传染性疾病的媒介载体。虫媒疾病具有传播速度快、扩散面积广和危害重等特点,不仅严重危害人类健康,还容易造成巨大的经济损失。由于针对虫媒传染病的药物匮乏以及虫媒病原对化学药物抗性的不断增加,阻断吸血昆虫的生殖成为控制虫媒疾病传播的有效措施。保幼激素(juvenile hormone, JH)和20-羟基蜕皮激素(20-hydroxyecdysone, 20E)在昆虫生殖过程中扮演着重要的角色。JH与胞内受体复合物Met/Tai结合后调控JH/Met靶基因表达,进而促进卵黄发生过程,为昆虫之后的吸血及产卵提供了必要条件;20E胞内受体为EcR/USP组成的异源二聚体,两者结合后激活下游基因表达,诱导卵黄原蛋白(vitellogenin, Vg)合成,为发育的卵巢提供营养。营养信号通路(胰岛素信号通路以及氨基酸介导的雷帕霉素靶蛋白信号通路)同样可以激活Vg合成,促进昆虫生殖;此外,营养信号通路与JH和20E之间可以相互作用共同调控吸血昆虫发育和繁殖。碳水化合物代谢以及脂代谢等能量代谢过程是昆虫生殖过程中主要能量来源,可以满足吸血昆虫生殖发育不同阶段极高的能量需求。研究表明,JH和20E信号通路在能量代谢过程中起着重要的调控作用;微小RNA在蚊虫这一类吸血昆虫中被证明与肠道微生物稳态、血液消化以及脂代谢等生理学过程密切相关,进一步影响了蚊虫卵巢发育。近年来,随着分子生物学及测序技术的革新,吸血昆虫生殖调控机制的研究不断取得新的进展。本文主要阐述了吸血昆虫生殖调控的分子机制研究进展,以期为通过调控吸血昆虫生殖的方法以阻断病原传播提供重要线索。     

Immune mechanisms in alcoholic liver disease

Growing evidence indicates that inflammatory reactions play an important role in the pathogenesis of alcoholic liver disease (ALD). The implication of immunity in fueling chronic inflammation in ALD has emerged from clinical and experimental evidence showing the recruitment and the activation of lymphocytes in the inflammatory infiltrates of ALD and has received further support by the recent demonstration of a role of Th17 lymphocytes in alcoholic hepatitis. Nonetheless, the mechanisms by which alcohol triggers adaptive immune responses are still incompletely characterized. Patients with advanced ALD show a high prevalence of circulating IgG and T-lymphocytes towards epitopes derived from protein modification by hydroxyethyl free radicals (HER) and end-products of lipid peroxidation. In both chronic alcohol-fed rats and heavy drinkers the elevation of IgG against lipid peroxidation-derived antigens is associated with an increased production of pro-inflammatory cytokines/chemokines and with the severity of histological signs of liver inflammation. Moreover, CYP2E1-alkylation by HER favors the development of anti-CYP2E1 auto-antibodies in a sub-set of ALD patients. Altogether, these results suggest that allo- and auto-immune reactions triggered by oxidative stress might contribute to fuel chronic hepatic inflammation during the progression of ALD.     

Immune effector mechanisms in parasitic infections

edited by F.Y. Liew and K. Vickerman, Philosophical Transactions of the Royal Society of London Series B, Vol. 352, No. 1359, 1997. pp 1293-1394, ISSN 0962-8436.     

Immune reactions of insects on bacterial pathogens and mutualists

In the past few years the knowledge of insect defense mechanisms against pathogenic microorganisms and parasites has significantly increased on both the molecular and the organismic level. These investigations have led to new concepts of immune protection also relevant for mammals with the identification of the Toll receptor family as an eminent example. This review provides a brief overview of insect strategies to on the one hand defeat bacterial pathogens while on the other hand cooperating with symbiotic bacteria beneficial for the insects.     

植食性昆虫对植物的反防御机制

本文综述了植食性昆虫对植物的反防御机制.一方面,植食性昆虫可通过其快速进化的寄主选择适应性,改变取食策略,调节生长发育的节律,以及规避自然天敌等抑制、逃避或改变植物的防御,即行为防御机制;另一方面,植食性昆虫可适应植物蛋白酶抑制剂、逃避植物防御伤信号、解毒植物次生物质,以及抑制植物阻塞反应来对植物防御进行反防御,即生理和生化防御机制.其中,昆虫抑制植物伤信号,防止植物阻塞反应是反防御机制的研究热点.昆虫反防御的研究有助于提高对昆虫-植物间协同进化关系的认识,并为害虫治理和抗虫植物的培育提供新的思路.     

Molecular-genetic mechanisms of the effect of developmental hormones in insects

A review of the available data on molecular mechanisms underlying the regulation of gene expression by the developmental hormone ecdysone and juvenile hormone. Heterodimer ESP/USP is the main ecdysone receptor in D. melanogaster. Structures similar to ESP/USP were found in other insects. The information about molecular-genetic mechanisms of the effect of juvenoids is less definite. It has been proposed that the juvenile hormone in insects is a modulator of the ecdysone effect.     

Opioid mechanisms in insects,with special attention toLeucophaea maderae

1. This review article provides information on the evolutionary history of neuroendocrine and related regulatory mechanisms. It focuses on the presence, diverse roles, and modes of operation of one class of neuropeptides, the endogenous opioids, in insects. 2. Opioid peptides, closely resembling those of vertebrates, have been identified in the brain and related neuroendocrine structures by means of immunocytochemistry and high-pressure liquid chromatography. 3. The demonstration of naloxone-sensitive, high-affinity binding sites for Met-enkephalin-like neuropeptides in the brain and digestive tract of Leucophaea deserves special attention because it provides new insights into the functional significance of opiate receptors paralleling those known in vertebrates. 4. Possible roles of receptor-mediated opioid systems in the insects discussed are regulation of the cyclicity of the female reproductive system, maintenance of normal midgut function mediated by the recurrent nerve, and locomotor activity.     

昆虫同域物种形成机制及检验

从生物学、生态和遗传的角度阐述昆虫同域物种形成过程中涉及到的可能性机制。昆虫同域种的分化与作用于同域初始种群的歧化选择密切相关,歧化选择间接导致种群生态特征和遗传特征的分化,促进同域近缘种群间的生殖隔离。同域物种形成的过程中涉及到性状替换、性选择、同型交配等机制。寄主专化型多见于昆虫同域种的分化过程中,一般以植食性昆虫为主。有关昆虫同域物种形成的检验机制有多种,归纳起来主要包括同型交配的检验、遗传漂流的量化、遗传分化程度和连锁不平衡(LD)的检测、杂交后代适合度的估算等。目前发现在许多昆虫种类中存在同域物种形成的可能性,但是有关其隔离机制并没有得到充分的解释。     

Molecular-genetic mechanisms of the effect of developmental hormones in insects

A review of the available data on molecular mechanisms underlying the regulation of gene expression by the developmental hormone ecdysone and juvenile hormone. Heterodimer ESP/USP is the main ecdysone receptor in D. melanogaster. Structures similar to ESP/USP were found in other insects. The information about molecular-genetic mechanisms of the effect of juvenoids is less definite. It has been proposed that the juvenile hormone in insects is a modulator of the ecdysone effect.