胶固素结合试验检测乙型肝炎特异性免疫复合物的研究

随着免疫学的进展,循环免疫复合物的检测越来越为人们所重视。一般认为某些肾炎、血管炎、关节炎、肝炎、雷诺氏病等皆由免疫复合物引起,并认为对血清、组织及体液中免疫复合物的测定,将为这些疾病的诊断、判断疗效及予后,提供新的依据。免疫复合物的检测分二大类:抗原非特异方法及抗原特异方法。我们将高桥熏报告中所用胶固索检测非特异性免疫     

抗人免疫球蛋白A、G、M类特异免疫酶偶联物的制备

<正>免疫应答是一个非常复杂的过程,在此过程中,各类抗体分子(IgA、IgG、IgM)起核心调节作用。所有抗体的主要功能是特异地结合抗原,人们据此免疫诊断各种疾病。 鉴于各类抗体的功能不同,抗体活性在免疫学表现中不是单价的,因此,在病毒、细菌、寄生虫等所引起的疾病中,测定特异抗体的类属性是完全必需的,在自身疾病中亦是如此。运用人的各种免疫球蛋白的特异抗体,以各种改良的免疫酶法可以达到此目的。而制备特异免疫酶偶联物是广泛运用这种方法的先决条件。     

T细胞抗原识别与活化研究

T细胞是通过其表面受体-T细胞抗原特异性受体（T cell antigen specific receptor,TCR）识别抗原并进行免疫应答的．T细胞如何识别以及清除抗原一直是分子免疫学研究的重点．免疫应答的重要过程是淋巴细胞的活化．而T细胞活化是细胞介导的免疫应答中不可缺少的内容．鉴于T细胞抗原识别和活化在免疫应答中的重要性．对近年来T细胞在抗原识别与活化研究方面所取得的重要进展进行了综述,并展望了T细胞的研究前景．     

固有免疫学的研究进展及其对研制新型免疫佐剂的启示

近年来,亚单位疫苗、DNA重组疫苗、合成肽疫苗等新型疫苗不断涌现,这些疫苗纯度高、特异性强。但其分子小,免疫原性较差,难以诱导机体产生有效的免疫应答,需添加佐剂来增强其免疫原性或增强宿主对抗原的保护性应答。免疫学的研究阐明了固有免疫如何调节适应性免疫。随着固有免疫学的发展和生化技术的提高,开发特异性更强、生物安全性更高的免疫佐剂越来越受到重视。对佐剂的分类、作用机理,固有免疫学的研究进展进行了综述,并就未来发展趋势提出自己的观点,为临床应用和进一步研制高效、低毒的免疫佐剂提供了参考。     

HLA-B27分子及其与强直性脊柱炎关联的研究进展简

HLA-B27是MHCI类分子,因而具有MHCI类分子的相关生物学特性。在正常免疫状态下,HLA-B27分子执行对内源性抗原如肿瘤及病毒的免疫监视及杀伤功能;但在机体免疫状态出现异常的情况下,它又可能成为引发自身免疫性疾病的主要相关因素,其中最为著名的是其与强制性脊柱炎（As）的关联研究。我们首先概述了HLA—B27分子正常免疫学功能的研究进展,然后对其在AS相关性研究中的进展进行了总结和分析。通过对上述两方面的综述与分析,全方位展示HLA-B27在执行免疫学功能和引发免疫病理性改变方面的作用,为全面认识和深入研究HLA-B27分子的生理与病理学作用提供坚实的基础。     

驯化免疫记忆样功能特征及其调控机制概述

固有免疫和适应性免疫是高等脊椎动物中相对独立又互相协同的两类免疫应答。经典的免疫学理论认为免疫记忆是适应性免疫区别于固有免疫的重要特征之一。然而,近年来发现的"驯化免疫"(trained immunity)现象显示,固有免疫细胞在接受病原体、细胞因子或其他代谢产物刺激后,可以通过表观遗传和代谢重编程等方式改变细胞表型,使其在再次活化时产生更强的非特异性免疫应答。驯化免疫现象的存在一方面使机体受到再次感染时,固有免疫系统可以同样发挥重要的保护作用;另一方面,过度激活的驯化免疫应答则可能导致炎症性疾病的发生发展。该文主要介绍了以卡介苗(Bacillus Calmette-Guérin, BCG)和β-葡聚糖为代表的驯化免疫应答特征及调控机制,并综述了驯化免疫这一新概念在疾病治疗和预防中的最新研究。     

HLA-B27分子及其与强直性脊柱炎关联的研究进展

HLA-B27是MHCⅠ类分子,因而具有MHCⅠ类分子的相关生物学特性。在正常免疫状态下,HLA-B27分子执行对内源性抗原如肿瘤及病毒的免疫监视及杀伤功能;但在机体免疫状态出现异常的情况下,它又可能成为引发自身免疫性疾病的主要相关因素,其中最为著名的是其与强制性脊柱炎(AS)的关联研究。我们首先概述了HLAB27分子正常免疫学功能的研究进展,然后对其在AS相关性研究中的进展进行了总结和分析。通过对上述两方面的综述与分析,全方位展示HLA-B27在执行免疫学功能和引发免疫病理性改变方面的作用,为全面认识和深入研究HLA-B27分子的生理与病理学作用提供坚实的基础。     

哺乳动物Toll样受体对结核分枝杆菌的控制

针对胞内菌结核分枝杆菌最为有效的免疫应答主要取决于天然免疫应答对侵入细菌的早期发现及获得性免疫应答的活化。Toll样受体在天然免疫应答发现分枝杆菌相关性分子和介导抗菌效应分子的分泌上起作用。它能调节一些免疫调节分子,这些分子能促进基于Th1细胞的T细胞发育。因此,Toll样受体的活化在抗微生物感染的机制上起一定的作用。     

克服腺病毒载体介导免疫应答的新策略:关闭淋巴细胞反应

近年来随着分子免疫学的迅速发展,人们对于自身免疫耐受机制以及病毒逃逸免疫应答的策略有了较多的认识。基于这些研究,多种抵抗腺病毒载体介导免疫反应的新策略正在被探讨之中。这些策略包括:1口服或胸腺内应用腺病毒载体或其抽提物;2应用CTLA4Ig可溶性分子或其表达载体;3开发修饰腺病毒载体。所有这些策略其最终机制都在于特异性地阻止或中断针对腺病毒载体的T淋巴细胞反应。     

MHC—I类分子抗原呈递机制的研究新进展

ＭＨＣ－１类分子限制性抗原提呈细胞免疫应答占有着重要地位,对其抗原呈递机制的研究一直是基础免疫学研究的热点,ＭＨＣ－Ｉ类分子限制性抗原呈递过程十分复杂,涉及到许多蛋白分子间的相互作用,一些伴侣分子如钙连接蛋白,钙网蛋白等在其中也起重要作用,本文从抗原多肽的处理,转运及其ＭＨＣ－Ｉ类分子－多肽复合物的分泌表达等３个方面概述了当前对其机制研究的新进展。     

THE PHYLOGENETIC RELATIONSHIP OF PFIESTERIA PISCICIDA, CRYPTOPERIDINIOPSOID SP. AMYLOODINOUM OCELLATUM AND A PFIESTERIA-LIKE DINOFLAGELLATE TO OTHER DINOFLAGELLATES AND APICOMPLEXANS

The taxonomic relationship between heterotrophic and parasitic dinoflagellates has not been studied extensively at the molecular level. In order to investigate these taxonomic relationships, we sequenced the small subunit (SSU) ribosomal RNA gene of Pfiesteria piscicida (Steidinger et Burkholder), a Pfiesteria -like dinoflagellate, Cryptoperidiniopsoid sp., and Amyloodinium ocellatum (Brown) and submitted those sequences to GenBank. Pfiesteria piscicida and Cryptoperidiniopsoid sp. are heterotrophic dinoflagellates, purportedly pathogenic to fish, and A. ocellatum, a major fish pathogen, has caused extensive economic losses in both the aquarium and aquaculture industries. The pathogenicity of the Pfiesteria -like dinoflagellate is unknown at this time, but its growth characteristics and in vitro food preferences are similar to those of P. piscicda. The SSU sequences of these species were aligned with the other full-length dinoflagellate sequences, as well as those of representative apicomplexans and Perkinsus species, the groups most closely related to dinoflagellates. Phylogenetic analyses indicate that Cryptoperidiniopsoid sp., P. piscicida, and the Pfiesteria -like dinoflagellate are closely related and group into the class Blastodiniphyceae, as does A. ocellatum. None of the species examined were closely related to the apicomplexans or to Perkinsus marinus, the parasite that causes "Dermo disease" in oysters. The overall phylogenetic analyses largely supported the current class and subclass groupings within the dinoflagellates.     

Piscinoodinium, a fish-ectoparasitic dinoflagellate, is a member of the class dinophyceae, subclass gymnodiniphycidae: convergent evolution with Amyloodinium

All dinoflagellates that infest the skin and gills of fish have traditionally been placed within the class Blastodiniphyceae. Their relatedness was primarily based upon a similar mode of attachment to the host, i.e., attachment disc with holdfasts. Results of recent molecular genetic analyses have transferred these parasites, including Amyloodinium, to the class Dinophyceae, subclass Peridiniphycidae. In our study, a small subunit rDNA gene from a parasitic dinoflagellate that has features diagnostic for species in the genus Piscinoodinium, i.e., typical trophont with attachment disc having rhizocysts, infesting the skin of freshwater tropical fish, places this organism within the dinophycean subclass Gymnodiniphycidae. This suggests a close relationship of Piscinoodinium spp. to dinoflagellates that include symbionts, e.g., species of Symbiodinium, and free-living algae, e.g., Gymnodinium spp. These molecular and morphological data suggest that evolution of this mode of fish ectoparasitism occurred independently in 2 distantly related groups of dinoflagellates, and they further suggest that the taxonomic status of parasites grouped as members of Piscinoodinium requires major revision.     

Propagation of the marine dinoflagellate Amyloodinium ocellatum under germ-free conditions

Germ-free infections of Amyloodinium ocellatum were produced on both living fish and in organ cultures. Exposing gnotobiotic guppies (Poecilia reticulata) to 125 dinospores in multiwell tissue culture plates produced nonlethal infections that could be serially propagated. Exposure to 250 or more parasites killed the fish during the first infection cycle, but if the dead fish were incubated in a cell culture medium/seawater mixture, the parasites could survive and reproduce for up to 2 wk in these organ cultures. Organ cultures containing only seawater or those containing bacteria did not support the prolonged survival of Amyloodinium.     

Massive infestation by Amyloodinium ocellatum (Dinoflagellida) of fish in a highly saline lake, Salton Sea, California, USA.

Persistent fish infestation by the parasitic dinoflagellate Amyloodinium ocellatum was found at a highly saline lake, Salton Sea, California, USA. The seasonal dynamics of the infestation of young tilapia was traced in 1997-1998. First appearing in May, it became maximal in June-August, decreased in October and was not detectable in November. Outbreak of the infestation and subsequent mortality of young fish was registered at the Sea at a water temperature and salinity of 40 degrees C and 46 ppt, respectively. Some aspects of the ultrastructure of parasitic trophonts of A. ocellatum and their location on the fish from different size groups are considered. The interactions of parasitological and environmental factors and their combined effect upon fish from the Salton Sea are discussed.     

Bacterial involvement in a saddleback disease of the reef silverside, At henna harringtonensis Goode (Pisces: Atherinidae) from Bermudan waters

Saddle-shaped skin lesions commonly occurring in both wild and captive Bermudan reef silversides yielded a mixed infection of motile and non-motile Gram-negative cells of Acinetobacter calcoaceticus, Aeromonas hydrophila, Pseudomonas sp., Vibrio parahaemolyticus and a myxobacterial-like strain. Bacteria occurred as almost pure microcolonies and mixed clumps on proximal scale and fin ray surfaces, in intercellular epidermal spaces, on perimysium of fin erector muscle myomeres and on eroded dorsal fin rays and their intact membranes, but neither on healthy areas of the skin nor within muscle cells. Effects were epithelial destruction and liquefactive necrosis of myomeres, and raising and sloughing of Malpighian cells, scales and dermis. Host response was minimal, consisting of infiltration of a few lymphocytes and macrophages. The fish pathogenic dinoflagellate Amyloodinium ocellatum was seen in one fish with a saddle lesion and caused muscle cell lysis, as evidenced by cloudy cell swelling. Antibiotic sensitivity tests showed increased drug resistance with mixed bacterial types compared to that of single pure isolates. This suggests that alternatives to chemotherapy for control of bacterial fish diseases is appropriate, because most are probably caused by mixed infections.     

A highly specific PCR assay for detecting the fish ectoparasite Amyloodinium ocellatum

Amyloodiniosis, caused by the dinoflagellate ectoparasite Amyloodinium ocellatum, is one of the most serious diseases affecting marine fish in warm and temperate waters. Current diagnostic methods rely entirely on the microscopic identification of parasites on the skin or gills of infested fish. However, subclinical infestations usually go undetected, while no method of detecting the free-swimming, infective (dinospore) stage has been devised. Targeting the parasite's ribosomal DNA region, we have developed a sensitive and specific PCR assay that can detect as little as a single cell from any of the 3 stages of the parasite's life cycle (trophont, tomont, dinospore). This assay performs equally well in a simple artificial seawater medium and in natural seawater containing a plankton community assemblage. The assay is also not inhibited by gill tissue. Sequence analysis of the internal transcribed spacer region of 5 A. ocellatum isolates, obtained from fish in the Red Sea (Israel), eastern Mediterranean Sea (Israel), Adriatic Sea (Italy), Gulf of Mexico (Florida), and from an unknown origin, revealed insignificant variation, indicating that all isolates were the same species. However, 3 of these isolates propagated in cell culture varied in behavior and morphology, and these differences were consistent during at least 2 yr in culture. Thus, our findings do not eliminate the possibility that different strains are in fact 'subspecies' or lower taxa, which may also differ in pathogenic and immunogenic characteristics, environmental tolerance, and other features.     

Protective immunity in fish against protozoan diseases

The demand for and costs of producing land-based animal protein continues to escalate as the world population increases. Fish is an excellent protein, but the catch-fishery is stagnant or in decline. Intensive cage culture of fish is a viable option especially in countries with lakes/rivers and/or a long coastline; however, disease outbreaks will likely occur more frequently with cage culture. Hence protective strategies are needed, and one approach is to exploit the piscine immune system. This discussion highlights immunity (innate/natural and adaptive/acquired) in fish against three pathogenic protozoa (Amyloodinium ocellatum, Ichthyophthirius multifiliis and Cryptobia salmositica). Histone-like proteins in the mucus and skin of naturally resistant fish kill trophonts of A. ocellatum, and also may cause abnormal development of tomonts. Breeding of Cryptobia-resistant brook charrs is possible as resistance is controlled by a dominant Mendelian locus, and the parasite is lysed via the Alternative Pathway of Complement Activation. Production of transgenic Cryptobia-tolerant salmon is an option. Recovered fish are protected from the three diseases (acquired immunity). Live I. multifiliis theronts injected intraperitoneally into fish elicit protection. Also, a recombinant immoblizing-antigen vaccine against ichthyophthirosis has been developed but further evaluations are necessary. The live Cryptobia vaccine protects salmonids from infections while the DNA-vaccine stimulates production of antibodies to neutralize the disease causing factor (metalloprotease) in cryptobiosis; hence infected fish recover more rapidly.     

Phylogeny of calcareous dinoflagellates as inferred from ITS and ribosomal sequence data

The phylogenetic relationships of calcareous dinoflagellates (i.e., Calciodinellaceae and Thoracosphaera) are investigated. Molecular data from the ribosomal 5.8S rRNA and highly conserved motifs of the ITS1 show Calciodinellaceae s.l. to be monophyletic when few non-calcareous taxa are included. They segregate into three monophyletic assemblages in a molecular analysis that considers the 5.8S rRNA and both the Internal Transcribed Spacer regions ITS1 and ITS2: a clade comprising species of Ensiculifera and Pentapharsodinium (E/P-clade), Scrippsiella s.l. (including fossil-based taxa such as Calciodinellum and Calcigonellum), and a heterogeneous group (T/P-clade) of calcareous (e.g., Thoracosphaera) and non-calcareous taxa (e.g., the highly toxic Pfiesteria). The potential to produce calcareous structures is considered as apomorphic within alveolates, and non-calcareous taxa nesting with calcareous dinoflagellates may have reduced calcification secondarily. Molecular results do not contradict general evolutionary scenarios provided by previous morphological (mainly paleontological) investigations.     

Host site of activity and cytological effects of histone-like proteins on the parasitic dinoflagellate Amyloodinium ocellatum

Histone-like proteins (HLPs) are broad-spectrum, endogenously produced antibiotics which we have isolated from tissues of rainbow trout Oncorhynchus mykiss and hybrid striped bass (Morone saxatilis male x M. chrysops female). Here, we show that HLP-1, which has high sequence homology to histone H2B, equally inhibited both young and mature trophonts of the important ectoparasite Amyloodinium ocellatum. In addition to direct killing of Amyloodinium trophonts, there was evidence that HLP-1 from both rainbow trout and hybrid striped bass caused severe developmental abnormalities, including delayed development, in both the parasitic trophont stage as well as the reproductive tomont stage. The deleterious effects of HLP-1 also were manifested in what appeared to be 'delayed mortality', where parasites of normal appearance would die later in development. Similar serious damage was also seen with calf histone H2B and the unrelated peptide antibiotic magainin 2. A comparison of the antibiotic activity in mucus versus epidermis compartments of the skin of hybrid striped bass suggested that the majority of antibiotic (including HLP-1) activity resided in the epidermis, although some activity was present in the mucus. These data suggest that normal, nonimmune fish skin contains potent defenses against protozoan ectoparasites and that the effects of these defenses may extend beyond their transient interactions with the parasites, which has important implications for this host-parasite relationship.