实验动物血液及精液感染弓形虫动态研究

采用荧光定量PCR技术对实验动物家兔血液及精液感染弓形虫DNA检测实验及动态变化研究,阐明了弓形虫感染的发展和转归机理,为了解弓形虫与宿主动态关系,弓形虫经血液、精液传播提供理论依据.对性传播疾病、特别是艾滋病的预防提供重要参考价值.     

乳腺癌实验动物模型的制备与应用

乳腺癌实验动物模型在研究人类乳腺癌的生物学行为及治疗等方面起着非常重要的作用。根据制备方法及研究目的的不同,乳腺癌实验动物模型可分为自发性、诱发性、移植性、转基因性及乳腺癌骨转移等动物模型,每种动物模型都有各自的特点和应用条件。     

泌尿道感染动物模型制作研究现状

建立与人类泌尿道感染相似的可靠动物模型,对探讨泌尿道感染发病机制和研究治疗方法十分必要。本文介绍了急性肾盂肾炎,慢性肾盂肾炎,腺性膀胱炎等泌尿道感染模型制作研究现状,并从菌种,品系等角度进行探讨。     

中枢神经系统隐球菌感染动物模型的研究

目的 构建中枢神经系统隐球菌感染的动物模型。方法 给予小鼠脑内接种隐球菌构建中枢神经系统隐球菌感染的动物模型。小鼠被随机地分为实验组和对照组,给予实验组小鼠脑内接种隐球菌菌悬液,对照组小鼠脑内接种生理盐水。结果 从组织病理方面观察到,实验组小鼠脑组织中的蛛网膜下腔、软脑膜表面、脑实质内、侧脑室脉络丛组织内均可见隐球菌菌体,脑膜轻度增生,侧脑室轻度扩大,脉络丛血管轻度扩张充血。对照组小鼠脑组织可见侧脑室轻度扩大,蛛网膜下腔血管、脑实质内血管、脉络丛血管均有轻度扩张充血,而蛛网膜下腔、软脑膜表面、脑实质内及侧脑室和室旁均未见隐球菌浸润。从组织病理观察结果两组具有一定的对比性。结论 小鼠脑内接种隐球菌构建其中枢神经系统隐球菌感染的模型,为研究人中枢神经系统隐球菌病提供了一个工具。     

建立胃癌实验动物模型方法的研究

目的通过对人低分化胃癌细胞系SGC-7901状态和接种细胞数目的研究,建立良好的皮下接种胃癌的动物模型。方法采用腹腔注射SGC-7901细胞,使裸鼠形成腹水;光镜及电镜观察细胞状态;将购买的SGC-7901细胞以及形成腹水后的肿瘤细胞分别以1×108、1×107和1×106个进行裸鼠皮下接种,每组接种5只。观察其肿瘤形成时间、大小、状态及病理学变化。结果SGC-7901细胞接种裸鼠形成腹水后进行培养的肿瘤细胞增殖状态发生改变;购买的SGC-7901细胞以1×108及1×107接种裸鼠,在第21天肿瘤组织中央均出现出血和坏死;1×106的裸鼠第21天未见肉眼可见的肿瘤形成。腹水培养的肿瘤细胞,接种1×108的裸鼠在第21天肿瘤组织中央可见大面积的出血和坏死;接种1×107及1×106的裸鼠在第21天均未见出血和坏死,接种1×107的肿瘤组织体积较大。结论SGC-7901细胞接种裸鼠形成腹水后的细胞,更容易建立SGC-7901细胞皮下接种的胃癌动物模型,其中以接种细胞数为1×107的肿瘤生长较好,更适用于胃癌的实验研究。     

结核病动物模型研究进展

结核病是由结核分枝杆菌感染引起的传染病,是危害人类健康的主要传染病之一。动物模型已经成为研究人类传染病的标准化工具。虽然对于结核分枝杆菌而言并没有真正意义的动物资源,但由于不同种类的动物,对分枝杆菌的敏感性不一样,因此可以成为结核病研究的有利工具。结核病最常用的实验动物模型包括小鼠、兔和豚鼠。每种动物有其自身特点,但并不能完全模拟人类疾病。通过建立结核病的动物模型,可以大大增加我们对疾病的病因、毒力和发病机制的理解。除了这三种模型外,非人灵长类也常被用于结核病的研究。本文总结了这几种结核病模型的研究状况。     

心力衰竭动物模型研究进展

心力衰竭是一种复杂的临床症候群,它是各种心脏病的终末阶段,发病率及病死率均较高,严重危害着人类健康,为了广泛深入地研究和治疗心力衰竭,迫切需要建立该病的动物模型。本综述复习了近年来文献,介绍目前较为成熟的心力衰竭动物模型的应用,同时比较之间的优缺点。     

SHIV-KB9感染中国恒河猴动物模型的建立

目的为了进一步确证SHIV-KB9感染中国恒河猴的病毒浓度范围,测试动物对病毒的适应性,明确该动物模型的可重复性。方法实验前采集猴血清并进行血清学检查。选出4只无SIV、STLV、SRV/D和B病毒感染的恒河猴,分别用10倍系列稀释的病毒液静脉感染实验猴,使用流氏细胞术、血常规、病毒分离、DNA-PCR和RT-PCR等方法确定实验猴是否被感染,以及感染后恒河猴体内病毒复制和免疫细胞损伤情况。结果实验猴的血浆病毒载量、病毒分离结果、CD4＋/CD8＋比值和CD4＋T细胞数等证实,4.8×105 copies/mL以上浓度的SHIV-KB9病毒液能成功感染中国恒河猴。结论本研究进一步明确了SHIV-KB9感染中国恒河猴的有效病毒浓度范围,确定了SHIV-KB9病毒感染中国恒河猴的病毒学、免疫学的测定指标,成功的建立了SHIV-KB9/中国恒河猴动物模型。     

动脉粥样硬化动物模型制作方法的介绍

动脉粥样硬化动物模型在病因学、病理学及预防方面的研究中起着非常重要的作用。近年来,运用兔子、小鼠、大鼠、鹌鹑等成功地建立了大量高脂饲料、单纯药物、高脂饲料加药物、基因敲除鼠及基因工程模型等诱导的动物模型。本文介绍了这几种动物模型的制作方法,以期为动脉粥样硬化的深入研究提供参考。     

肝纤维化的实验动物模型

本文讨论了建立肝纤维化动物模型的技术与存在的问题,以大鼠为主要动物讨论了目前常用的几种造模方法、每种造模方法的致病机理、造模途径、效果,同时比较了不同造模方法的优缺点及各自的用途,提出了肝纤维化动物模型领域的研究方向。     

Construction of Toxoplasma gondii bradyzoite expressing the green fluorescent protein

The bradyzoite stage of Toxoplasma gondii is a key step in the parasite life cycle. For a better understanding of this stage, a sensitive system to detect the tissue cysts would be required. In this study, we generated the T. gondii cyst-forming strain PLK expressing green fluorescent protein (GFP) under control of the dense granule protein 1 promoter, which works at both the tachyzoite and the bradyzoite stages. The bradyzoites with GFP fluorescence within both small and large cysts were detectable in the brain of mice infected with the recombinant PLK. Indeed, the bradyzoites expressing GFP had infectivity to mice. This study shows that transfection of the cyst-forming strain with GFP gene under control of the GRA1 promoter could be a useful approach for the study of the bradyzoite stage of T. gondii.     

Dynamin inhibitor impairs Toxoplasma gondii invasion

The protozoan parasite Toxoplasma gondii infects its host cells through an active mechanism. In this work, we obtained evidence that host cells also play a fundamental role during the infection process. We found that previous incubation of the host cells, but not the parasites, with Dynasore, a small molecule that inhibits dynamin GTPase activity, markedly reduced the penetration of T. gondii tachyzoites into LLC-MK2 cells. In contrast, parasite adhesion to the host cell surface increased, as observed both by light and electron microscopy. Intriguingly, the few parasites internalized by Dynasore-treated cells remained in vacuoles located at the periphery of the cell, in contrast to the perinuclear localization seen in the control.     

Hydroxyurea inhibits intracellular Toxoplasma gondii multiplication

Tachyzoites of Toxoplasma gondii multiply within the parasitophorous vacuole (PV) until the lysis of the host cell. This study was undertaken to evaluate the effect of hydroxyurea (a specific drug that arrests cell division at G1/S phase) on the multiplication of T. gondii tachyzoites in infected Vero cells. Infected host cells were treated with hydroxyurea for periods varying from 5 to 48 h, and the survival and morphology of the parasite were determined. Hydroxyurea arrested intracellular T. gondii multiplication in all periods tested. After 48 h of incubation with hydroxyurea, intracellular parasites were not easily observed in Vero cells. Ultrastructural observations showed that infected host cells treated with hydroxyurea for 24 h or more presented disrupted intracellular parasites within the PV. However, the host cells exhibited a normal morphology. Our observations suggest that hydroxyurea was able to interfere with the cycle of the intracellular parasite, leading to the complete destruction of the T. gondii without affecting the host cells.     

Proteomic analysis of calcium-dependent secretion in Toxoplasma gondii

Toxoplasma gondii is an intracellular protozoan parasite that invades a wide range of nucleated cells. In the course of intracellular parasitism, the parasite releases a large variety of proteins from three secretory organelles, namely, micronemes, rhoptries and dense granules. Elevation of intracellular Ca(2+) in the parasite causes microneme discharge, and microneme secretion is essential for the invasion. In this study, we performed a proteomic analysis of the Ca(2+)-dependent secretion to evaluate the protein repertoire. We found that Ca(2+)-mobilising agents, such as thapsigargin, NH(4)Cl, ethanol and a Ca(2+) ionophore, A23187, promoted the secretion of the parasite proteins. The proteins, artificially secreted by A23187, were used in a comparative proteomic analysis by 2-DE followed by PMF analysis and/or N-terminal sequencing. Major known microneme proteins (MICs), such as MIC2, MIC4, MIC6 and MIC10 and apical membrane antigen 1 (AMA1), were identified, indicating that the proteomic analysis worked accurately. Interestingly, new members of secretory proteins, namely rhoptry protein 9 (ROP9) and Toxoplasma SPATR (TgSPATR), which was a homologue of a Plasmodium secreted protein with an altered thrombospondin repeat (SPATR), were detected in Ca(2+)-dependent secretion. Thus, we succeeded in detecting Ca(2+)-dependent secretory proteins in T. gondii, which contained novel secretory proteins.     

Characterization of a new gene WX2 in Toxoplasma gondii

Using hybridization techniques, we prepared the monoclonal antibody （Mab） 7C3-C3 against Toxoplasma gondii. The protection tests showed that the protein （Mab7C3-C3） inhibited the invasion and proliferation of T. gondii RH strain in HeLa cells. The passive transfer test indicated that the antibody significantly prolonged the survival time of the challenged mice. It was also shown that the antibody could be used for the detection of the circulating antigen of T. gondii. After immunoscreening the T. gondii tachyzoite cDNA library with Mab7C3-C3, a new gene wx2 of T. gondii was obtained. Immunofluorescence analysis showed that the WX2 protein was located on the membrane of the parasite. Nucleotide sequence comparison showed 28% identity to the calcium channel α-IE unit and shared with the surface antigen related sequence in some conservative residues. However, no match was found in protein databases. Therefore, it was an unknown gene in T. gondii encoding a functional protein on the membrane of T. gondii. Because it has been shown to have a partial protective effect against T. gondii infection and is released as a circulating antigen, it could be a candidate molecule for vaccine or a novel target for new drugs.     

Proteomic profiling of extracellular vesicles secreted from Toxoplasma gondii

Toxoplasma gondii infects a wide range of hosts worldwide, including humans and domesticated animals causing toxoplasmosis disease. Recently, exosomes, small extracellular vesicles (EV) that contain nucleic acids, proteins, and lipids derived from their original cells were linked with disease protection. The effect of EVs derived from T. gondii on the immune response and its relevance in a physiological context is unknown. Here we disclose the first proteomic profiling of T. gondii EVs compared to EVs isolated from a human foreskin fibroblast infected cell line cultured in a vesicle‐free medium. Our results reveal a broad range of canonical exosomes proteins. Data are available via ProteomeXchange with the identifier PXD004895.     

Antigenemia and Specific IgM and IgG Antibody Responses in Rabbits Infected with Toxoplasma gondii

In this experiment, the correlation between antigenemia and specific antibody responses in Toxoplasma gondii-infected rabbits was assessed. We injected 1,000 T. gondii tachyzoites (RH) subcutaneously into 5 rabbits. Parasitemia, circulating antigens, and IgM and IgG antibody titers in blood were tested by ELISA and immunoblot. For detection of parasitemia, mice were injected with blood from rabbits infected with T. gondii and mice died between days 2 and 10 post-infection (PI). Circulating antigens were detected early on day 2 PI, and the titers increased from day 4 PI and peaked on day 12 PI. Anti-Toxoplasma IgM antibody titers increased on day 6 PI and peaked on days 14-16 PI. IgG was detected from day 10 PI, and the titers increased continuously during the experiment. The antigenic protein patterns differed during the infection period, and the number of bands increased with ongoing infection by the immunoblot analysis. These result indicated that Toxoplasma circulating antigens during acute toxoplasmosis are closely related to the presence of parasites in blood. Also, the circulating antigen levels were closely correlated with IgM titers, but not with IgG titers. Therefore, co-detection of circulating antigens with IgM antibodies may improve the reliability of the diagnosis of acute toxoplasmosis.     

3-D Imaging and Analysis of Neurons Infected In Vivo with Toxoplasma gondii

Toxoplasma gondii is an obligate, intracellular parasite with a broad host range, including humans and rodents. In both humans and rodents, Toxoplasma establishes a lifelong persistent infection in the brain. While this brain infection is asymptomatic in most immunocompetent people, in the developing fetus or immunocompromised individuals such as acquired immune deficiency syndrome (AIDS) patients, this predilection for and persistence in the brain can lead to devastating neurologic disease. Thus, it is clear that the brain-Toxoplasma interaction is critical to the symptomatic disease produced by Toxoplasma, yet we have little understanding of the cellular or molecular interaction between cells of the central nervous system (CNS) and the parasite. In the mouse model of CNS toxoplasmosis it has been known for over 30 years that neurons are the cells in which the parasite persists, but little information is available about which part of the neuron is generally infected (soma, dendrite, axon) and if this cellular relationship changes between strains. In part, this lack is secondary to the difficulty of imaging and visualizing whole infected neurons from an animal. Such images would typically require serial sectioning and stitching of tissue imaged by electron microscopy or confocal microscopy after immunostaining. By combining several techniques, the method described here enables the use of thick sections (160 µm) to identify and image whole cells that contain cysts, allowing three-dimensional visualization and analysis of individual, chronically infected neurons without the need for immunostaining, electron microscopy, or serial sectioning and stitching. Using this technique, we can begin to understand the cellular relationship between the parasite and the infected neuron.     

载体介导的刚地弓形虫MIC疫苗的研制现状

刚地弓形虫引起的弓形虫病是一种严重危害人类健康的人兽共患寄生虫病,采用疫苗防治该病是当前研究的热点领域之一。MIC抗原是一种有效的疫苗候选分子,本研究综述了鼠伤寒沙门菌、卡介苗、格登链球菌、腺病毒血清型5和假狂犬病毒等载体介导的刚地弓形虫MIC疫苗的研制现状。     

Membrane fluidity of Toxoplasma gondii: a fluorescence polarization study

Toxoplasma gondii membrane fluidity was investigated by fluorescence polarization. We used 1,6-diphenyl 1,3,5-hexatriene (DPH) as a fluorescent hydrophobic probe. Fluorescence anisotropy (r) and degree of order (s) showed high fluidity properties. Chemical analysis was performed on this parasite. We found a low cholesterol/phospholipid ratio, many unsaturated fatty acids chains, and high phosphatidylcholine and low sphingomyelin amounts. These results were in good agreement with the observed high fluidity. This may be related to the great adaptability of Toxoplasma gondii in infesting a wide variety of host cells.