急性淋巴细胞白血病CD34+CD38-细胞在NOD/SCID小鼠体内的自我更新与增值能力

目的 探索急性淋巴细胞白血病(ALL)患者CD34+ CD38-细胞移植到NOD/SCID小鼠体内建立白血病的可行性、自我更新与增殖潜能.方法 分选并鉴定ALL患者骨髓CD34+ CD38-细胞及对照CD34- CD38+细胞后,经尾静脉分别注射104个细胞于亚致死剂量射线照射的NOD/SCID小鼠体内,连续监测小鼠状态以及外周血血象改变,对濒死或死亡小鼠进行骨髓检查、肝脾病理学检查.结果 接种从ALL患者分选的CD34+ CD38-细胞到NOD/SCID小鼠体内后4周,小鼠外周血白细胞上升,到8周左右达高峰,约15×109～20× 109/L,原始及幼稚淋巴细胞明显增多.骨髓象显示以原始及幼稚淋巴细胞增生为主,约为40％,且肝脾组织也有白细胞浸润,明显高于接种了对照组CD34- CD38+细胞的NOD/SCID小鼠.结论 ALL患者CD34+CD38-细胞可以成功移植NOD/SCID 小鼠,在小鼠体内增殖形成白血病,说明该群细胞具有自我更新和增殖的潜能,可作为探索白血病起始细胞研究的重要载体.     

急性淋巴细胞白血病CD34~+ CD38~-细胞在NOD/SCID小鼠体内的自我更新与增殖能力

目的探索急性淋巴细胞白血病(ALL)患者CD34+CD38-细胞移植到NOD/SCID小鼠体内建立白血病的可行性、自我更新与增殖潜能。方法分选并鉴定ALL患者骨髓CD34+CD38-细胞及对照CD34-CD38+细胞后,经尾静脉分别注射104个细胞于亚致死剂量射线照射的NOD/SCID小鼠体内,连续监测小鼠状态以及外周血血象改变,对濒死或死亡小鼠进行骨髓检查、肝脾病理学检查。结果接种从ALL患者分选的CD34+CD38-细胞到NOD/SCID小鼠体内后4周,小鼠外周血白细胞上升,到8周左右达高峰,约15×109～20×109/L,原始及幼稚淋巴细胞明显增多。骨髓象显示以原始及幼稚淋巴细胞增生为主,约为40%,且肝脾组织也有白细胞浸润,明显高于接种了对照组CD34-CD38+细胞的NOD/SCID小鼠。结论 ALL患者CD34+CD38-细胞可以成功移植NOD/SCID小鼠,在小鼠体内增殖形成白血病,说明该群细胞具有自我更新和增殖的潜能,可作为探索白血病起始细胞研究的重要载体。     

不同维生素免疫调节作用在鼠疟模型中的实验观察

探讨不同维生素对P. y17XL感染BALB/c小鼠的免疫调节作用。将6~8周龄,雌性BALB/c小鼠,随机分为维生素（ V）处理组和对照组。 V处理组小鼠分别经50 mg/kg VA、600 mg/kg VE 或1 g/只VC连续10 d灌胃,0.2 mL/只;对照组小鼠分别给予相同剂量的溶剂（大豆油或生理盐水）处理。之后,各组小鼠分别经腹腔接种1＆#215;106 P. y17XL寄生的红细胞,动态观察感染小鼠原虫血症水平和生存率;流式细胞术检测感染后第0、3和5天小鼠脾细胞树突状细胞（ DCs）亚群（ pDCs与mDCs）百分比及功能分子（ TLR9和MHC域）的表达。与对照组相比,VA和VE处理组小鼠原虫血症水平升高,生存率降低;感染后第5天脾细胞中pDCs与mDCs亚群水平以及DCs表面受体TLR9和表面分子MHC域的表达水平显著下降。相反,VC处理组小鼠原虫血症水平降低,生存率延长,pDCs与mDCs亚群以及TLR9和MHC域的表达水平显著升高。结果表明,不同维生素对疟疾感染产生不同的调控作用,VA和VE通过抑制DCs数量和功能,加重疟疾感染,而VC则促进DCs数量和功能,推迟感染进程。     

NOD/SCID小鼠模型在实验血液学研究中的应用

NOD/SCID（非肥胖糖尿病/重症联合免疫缺陷）小鼠是在SCID（重症联合免疫缺陷）小鼠的基础上与非肥胖性糖尿病小鼠（NOD/Lt）品系回交的免疫缺陷鼠。NOD/SCID小鼠既有先天免疫缺陷,又有T和B淋巴细胞缺乏,各种肿瘤细胞可以植入,且较少发生排斥反应及移植物抗宿主病（GVHD）,所以NOD/SCID小鼠逐渐成为血液学实验研究的有用工具。本文从NOD/SCID小鼠的生物学特性、建立人类白血病模型、干细胞移植、药物研究及NOD/SCID小鼠应用中存在的不足和改良等方面综合述评。     

BALB/c小鼠感染不同疟原虫CD4＋ Th应答和凋亡特点的比较研究

探讨不同疟原虫感染BALB/c小鼠的免疫应答特点。BALB/c小鼠经腹腔注射致死型约氏疟原虫（P.y17XL）和夏氏疟原虫（P.cAS）感染的红细胞,计数红细胞感染率;ELISA动态检测感染小鼠脾细胞培养上清中IFN-γ和IL-4水平;流式细胞术检测脾中CD4＋T细胞凋亡数量。约氏疟原虫（P.y17XL）感染早期,小鼠原虫血症持续上升;IFN-γ和IL-4分泌水平仅在感染后第3天出现一过性有意义的升高,而且峰值较低;脾中CD4＋T细胞大量凋亡,小鼠全部死亡;而夏氏疟原虫（P.cAS）感染小鼠,原虫血症上升缓慢;IFN-γ分泌水平在感染后第5天达峰值;IL-4分泌水平在感染后第10天达峰值,且峰值较高维持时间较长;脾中CD4＋T细胞凋亡细胞于感染后8 d出现有意义升高,小鼠全部存活。抗疟保护性免疫有赖于Th1和Th2型免疫应答的有效建立和协调过渡,感染期间CD4＋T细胞凋亡的时相和数量可能是影响免疫应答的强度或引起宿主免疫抑制的原因,从而影响宿主疟原虫感染的结局。     

特异性IgG抗体在异种/同种异株疟原虫感染治愈后P.y17XL再感染中的保护作用

为探讨特异性IgG抗体在异种/同种异株疟原虫治愈后再感染过程中的作用,用不同种/株疟原虫感染BALB/c小鼠,经治愈后用P.y17XL再感染。通过计数红细胞感染率和检测再感染后血清中特异性IgG抗体的水平变化,发现P.y17XNL感染治愈组小鼠几乎不出现原虫血症,其余异种疟原虫感染治愈组小鼠出现了不同程度的虫血症发生时相延迟和水平降低,部分生存率有所延长;不同虫种/株感染治愈后P.y17XL再感染的小鼠IFN-γ水平均明显低于同时间点P.y17XL初次感染的小鼠;P.v、P.y17XNL感染治愈小鼠血清中P.y17XL特异性IgG抗体水平出现显著增加(P<0.05),且以IgG1亚类升高为主。表明特异性IgG抗体可在宿主抗同源疟原虫再感染中发挥着重要作用,而对异种疟原虫再感染保护性有限。     

虎源H5N1亚型禽流感病毒感染小鼠模型的建立

为研究H5N1亚型禽流感病毒的病原特性、致病机理及对其疫苗与救治药物效果评价提供平台,利用本室分离鉴定的虎源A/Tiger/Harbin/01/2002株(简称HAB/01)H5N1亚型禽流感病毒进行连续10倍稀释后,对4～6周龄 雄性BALB/c小鼠经乙醚麻醉后进行滴鼻攻毒,每个稀释度接种10只实验小鼠,测定其MLD50,检测小鼠感染、致病的多项指标,观察期为14d.结果感染小鼠呈现出规律的以肺炎为主的临床症状、病理变化及病死率;测得该病毒对小鼠的MLD50为10-7.1/0.05mL.成功建立了虎源H5N1亚型禽流感病毒感染BALB/c小鼠的实验模型.     

不同种株利什曼原虫对Balb/c小鼠和金黄地鼠的致病性研究

为了比较不同种株利什曼原虫对实验动物的致病性,分别将5×107的杜氏利什曼原虫SC6株、热带利什曼原虫K27株、婴儿利什曼原虫LEM235株和婴儿利什曼原虫KXG-Liu株前鞭毛体与无鞭毛体感染Balb/c小鼠和金黄地鼠,观察各感染动物皮肤损害状况,3月后,有限稀释培养法分别检测肝和脾脏内的虫荷数.发现不同种株利什曼原虫引起的疾病存在极大的异质性,杜氏利什曼原虫四川SC6株致Balb/c小鼠轻微皮肤损害,肝和脾脏内重度虫荷数,金黄地鼠肝和脾脏内重度虫荷数;热带利什曼原虫K27株致Balb/c小鼠严重的皮肤损害,但肝和脾脏的虫荷数较低,金黄地鼠肝和脾脏中未查见原虫;婴儿利什曼原虫LEM235株致Balb/c小鼠严重的皮肤损害,肝和脾脏内重度虫荷数,金黄地鼠肝和脾脏内重度虫荷数;婴儿利什曼原虫KXG-Liu株可致Balb/c小鼠严重的皮肤损害,肝和脾脏中度虫荷数,金黄地鼠肝和脾脏内少量虫荷数.另外,还发现原虫的生活史状态和进入机体的途径及实验动物的类型对不同种株利什曼原虫感染致病产生影响.     

七种实验动物对沙鼠利什曼原虫感受性的研究

本文报道3株近交系小鼠、沙鼠和仓鼠对沙鼠利什曼原虫的感受性。结果表明,BALB/c株小鼠,长爪沙鼠和黑线仓鼠对沙鼠利什曼有较好的感受性。CFW株小鼠感染后不久即可自愈,而C57 BL株鼠则抗拒感染。除了黑线仓鼠的睾丸在感染原虫后偶可产生转移性皮肤损害外,其余实验动物的感染均仅局限在接种部位的皮肤,进一步表明沙鼠利什曼是一种亲皮肤性的原虫。     

人脐血CD34+细胞在NOD/SCID小鼠免疫重建及其抗HBV作用的初步探讨

目的：探讨NOD／SCID（nonobese diabetic／severe combined immunodeficient）小鼠移植人脐带血（human umbilical cord blood,HUCB）CD34＋细胞后免疫重建的特性。建立hu—NOD／SCID人鼠嵌合模型并观察其人源化免疫细胞在小鼠体内的生长分化特性、存活时间及其对HBV感染的清除作用。方法：1．NOD／SCID小鼠于C0603．5Gy照射后24h内尾静脉输注HUCBCD34＋细胞;2．以流式细胞技术鉴定小鼠外周血中CD45＋,CD3＋,CD19＋,CD56＋等人源化细胞的比例;3．NOD／SCID小鼠于移植后第4wk注射HBV感染者血清并以未移植的NOD／SCID小鼠作为对照,注射同等量的患者血清;4．于感染后1、7、10、15天采血,免疫荧光定量PCR方法分别检测其HBV—DNA含量。结果：1．HUCBCD34＋细胞移植后第2wk,在小鼠外周血中检测出的CD3＋CD8＋T细胞、CD3＋CD4＋T细胞、CD19＋B细胞、CD56＋NK细胞的比例分别为18．6％、16．1％、13．1％和27．8％。各细胞比例随小鼠周龄而变化。所有移植小鼠存活时间均达9wk;2．移植后小鼠感染HBV血清后,病毒仅在感染后第一天检出,随后消失;未移植CD34＋细胞的小鼠外周血HBV—DNA一直维持在103水平：结论：1．NOD／SCID小鼠经射线照射后移植HUCBCD34＋细胞,在不加任何刺激因子的情况下小鼠可以长时间存活并重建免疫;2．hu—NOD／SCID人鼠嵌合模型小鼠免疫成功重建后,对HBV感染有快速的清除作用。     

Human erythroid cells produced ex vivo at large scale differentiate into red blood cells in vivo

New sources of red blood cells (RBCs) would improve the transfusion capacity of blood centers. Our objective was to generate cells for transfusion by inducing a massive proliferation of hematopoietic stem and progenitor cells, followed by terminal erythroid differentiation. We describe here a procedure for amplifying hematopoietic stem cells (HSCs) from human cord blood (CB) by the sequential application of specific combinations of growth factors in a serum-free culture medium. The procedure allowed the ex vivo expansion of CD34+ progenitor and stem cells into a pure erythroid precursor population. When injected into nonobese diabetic, severe combined immunodeficient (NOD/SCID) mice, the erythroid cells were capable of proliferation and terminal differentiation into mature enucleated RBCs. The approach may eventually be useful in clinical transfusion applications.     

Gene expression profiles of cryopreserved CD34 human umbilical cord blood cells are related to their bone marrow reconstitution abilities in mouse xenografts

Human umbilical cord blood (UCB) cells are an alternative source of hematopoietic stem cells for treatment of leukemia and other diseases. It is very difficult to assess the quality of UCB cells in the clinical situation. Here, we sought to assess the quality of UCB cells by transplantation to immunodeficient mice. Cryopreserved CD34⁺ UCB cells from twelve different human donors were transplanted into sublethally irradiated NOD/shi-scid Jic mice. In parallel, the gene expression profiles of the UCB cells were determined from oligonucleotide microarrays. UCB cells from three donors failed to establish an engraftment in the host mice, while the other nine succeeded to various extents. Gene expression profiling indicated that 71 genes, including HOXB4, C/EBP-β, and ETS2, were specifically overexpressed and 23 genes were suppressed more than 2-fold in the successful UCB cells compared to those that failed. Functional annotation revealed that cell growth and cell cycle regulators were more abundant in the successful UCB cells. Our results suggest that hematopoietic ability may vary among cryopreserved UCB cells and that this ability can be distinguished by profiling expression of certain sets of genes.     

De Novo Generated Human Red Blood Cells in Humanized Mice Support Plasmodium falciparum Infection

Immunodeficient mouse–human chimeras provide a powerful approach to study host specific pathogens like Plasmodium (P.) falciparum that causes human malaria. Existing mouse models of P. falciparum infection require repeated injections of human red blood cells (RBCs). In addition, clodronate lipsomes and anti-neutrophil antibodies are injected to suppress the clearance of human RBCs by the residual immune system of the immunodeficient mice. Engraftment of NOD-scid Il2rg^-/- mice with human hematopoietic stem cells leads to reconstitution of human immune cells. Although human B cell reconstitution is robust and T cell reconstitution is reasonable in the recipient mice, human RBC reconstitution is generally poor or undetectable. The poor reconstitution is mainly the result of a deficiency of appropriate human cytokines that are necessary for the development and maintenance of these cell lineages. Delivery of plasmid DNA encoding human erythropoietin and interleukin-3 into humanized mice by hydrodynamic tail-vein injection resulted in significantly enhanced reconstitution of erythrocytes. With this improved humanized mouse, here we show that P. falciparum infects de novo generated human RBCs, develops into schizonts and causes successive reinvasion. We also show that different parasite strains exhibit variation in their ability to infect these humanized mice. Parasites could be detected by nested PCR in the blood samples of humanized mice infected with P. falciparum K1 and HB3 strains for 3 cycles, whereas in other strains such as 3D7, DD2, 7G8, FCR3 and W2mef parasites could only be detected for 1 cycle. In vivo adaptation of K1 strain further improves the infection efficiency and parasites can be detected by microscopy for 3 cycles. The parasitemia ranges between 0.13 and 0.25% at the first cycle of infection, falls between 0.08 and 0.15% at the second cycle, and drops to barely detectable levels at the third cycle of infection. Compared to existing mouse models, our model generates human RBCs de novo and does not require the treatment of mice with immunomodulators.     

Competing for blood: the ecology of parasite resource competition in human malaria–helminth co‐infections

Ecological theory suggests that co‐infecting parasite species can interact within hosts directly, via host immunity and/or via resource competition. In mice, competition for red blood cells (RBCs) between malaria and bloodsucking helminths can regulate malaria population dynamics, but the importance of RBC competition in human hosts was unknown. We analysed infection density (i.e. the concentration of parasites in infected hosts), from a 2‐year deworming study of over 4000 human subjects. After accounting for resource‐use differences among parasites, we find evidence of resource competition, priority effects and a competitive hierarchy within co‐infected individuals. For example reducing competition via deworming increased Plasmodium vivax densities 2.8‐fold, and this effect is limited to bloodsucking hookworms. Our ecological, resource‐based perspective sheds new light into decades of conflicting outcomes of malaria–helminth co‐infection studies with significant health and transmission consequences. Beyond blood, investigating within‐human resource competition may bring new insights for improving human health.     

In Vivo Assessment of Rodent Plasmodium Parasitemia and Merozoite Invasion by Flow Cytometry

During blood stage infection, malaria parasites invade, mature, and replicate within red blood cells (RBCs). This results in a regular growth cycle and an exponential increase in the proportion of malaria infected RBCs, known as parasitemia. We describe a flow cytometry based protocol which utilizes a combination of the DNA dye Hoechst, and the mitochondrial membrane potential dye, JC-1, to identify RBCs which contain parasites and therefore the parasitemia, of in vivo blood samples from Plasmodium chabaudi adami DS infected mice. Using this approach, in combination with fluorescently conjugated antibodies, parasitized RBCs can be distinguished from leukocytes, RBC progenitors, and RBCs containing Howell-Jolly bodies (HJ-RBCs), with a limit of detection of 0.007% parasitemia. Additionally, we outline a method for the comparative assessment of merozoite invasion into two different RBC populations. In this assay RBCs, labeled with two distinct compounds identifiable by flow cytometry, are transfused into infected mice. The relative rate of invasion into the two populations can then be assessed by flow cytometry based on the proportion of parasitized RBCs in each population over time. This combined approach allows the accurate measurement of both parasitemia and merozoite invasion in an in vivo model of malaria infection.     

Intrahepatic transplantation of CD34+ cord blood stem cells into newborn and adult NOD/SCID mice induce differential organ engraftment

In vivo studies concerning the function of human hematopoietic stem cells (HSC) are limited by relatively low levels of engraftment and the failure of the engrafted HSC preparations to differentiate into functional immune cells after systemic application. In the present paper we describe the effect of intrahepatically transplanted CD34⁺ cells from cord blood into the liver of newborn or adult NOD/SCID mice on organ engraftment and differentiation.Analyzing the short and long term time dependency of human cell recruitment into mouse organs after cell transplantation in the liver of newborn and adult NOD/SCID mice by RT-PCR and FACS analysis, a significantly high engraftment was found after transplantation into liver of newborn NOD/SCID mice compared to adult mice, with the highest level of 35% human cells in bone marrow and 4.9% human cells in spleen at day 70. These human cells showed CD19 B-cell, CD34 and CD38 hematopoietic and CD33 myeloid cell differentiation, but lacked any T-cell differentiation. HSC transplantation into liver of adult NOD/SCID mice resulted in minor recruitment of human cells from mouse liver to other mouse organs. The results indicate the usefulness of the intrahepatic application route into the liver of newborn NOD/SCID mice for the investigation of hematopoietic differentiation potential of CD34⁺ cord blood stem cell preparations.     

The in vivo distribution of 51Cr-labeled Trypanosoma cruzi in mice

The optimal conditions for labeling Trypanosoma cruzi culture forms with ⁵¹CrO₄²⁻ were determined. Labeled trypanosomes or labeled human red blood cells (RBCs) were injected intravenously into normal C3H(He) female mice and the rate of clearance and organ distribution of the isotope were observed over a 30 h period. It was found that trypanosomes and xenogeneic RBCs were cleared rapidly from the peripheral blood and accumulated primarily in the liver, spleen, lungs and kidneys. A difference was noted in accumulation of trypanosomes and RBCs in these mice.     

The course of infections and pathology in immunomodulated NOD/LtSz-SCID mice inoculated with Plasmodium falciparum laboratory lines and clinical isolates

Human chimeras are potentially invaluable models for hemoprotozoan parasites such as Plasmodium falciparum. The work presented assesses the susceptibility of immunomodulated NOD/LtSz-SCID mice to genetically distinct P. falciparum parasites. To this end, mice grafted with human erythrocytes were inoculated with two P. falciparum laboratory lines, 3D7 and Dd2 and four clinical isolates, ISCIII-230, ISCIII-231, ISCIII-381 and ISCIII-399. The results showed that, without a previous period of parasite adaptation, 100% of the inoculated mice developed an infection, generally self-limited, though some mice died. The parasitemias ranged from 0.05 to 8% and lasted an average of 19 days (15-26 days) depending on the line or isolate studied. Sexual forms of different maturity, stage II-IV and mature gametocytes were observed in the peripheral blood of mice in 22, 50, 25, 72 and 80% of the mice infected with Dd2, ISCIII-399, ISCIII-230, ISCIII-231 and ISCIII-381 isolates, respectively. The study of the clinical symptoms, the haematological parameters and the histopathological changes in the infected mice showed that most of the malaria features were present in the infected mice except that the sequestration of infected erythrocytes was absent or at most a minor phenomenon, as also indicated by the presence of mature forms of the parasites in the peripheral blood. This study shows that the human chimeras allow the complete asexual and sexual erythrocytic cycle of different P. falciparum lines and clinical isolates to be observed in vivo. It opens a new way to investigate any parasite population in terms of infectivity, transmission, and drug resistance.     

Functional human T lymphocyte development from cord blood CD34+ cells in nonobese diabetic/Shi-scid,IL-2 receptor gamma null mice

An experimental model for human T lymphocyte development from hemopoietic stem cells is necessary to study the complex processes of T cell differentiation in vivo. In this study, we report a newly developed nonobese diabetic (NOD)/Shi-scid, IL-2Rgamma null (NOD/SCID/gamma(c)(null)) mouse model for human T lymphopoiesis. When these mice were transplanted with human cord blood CD34(+) cells, the mice reproductively developed human T cells in their thymus and migrated into peripheral lymphoid organs. Furthermore, these T cells bear polyclonal TCR-alphabeta, and respond not only to mitogenic stimuli, such as PHA and IL-2, but to allogenic human cells. These results indicate that functional human T lymphocytes can be reconstituted from CD34(+) cells in NOD/SCID/gamma(c)(null) mice. This newly developed mouse model is expected to become a useful tool for the analysis of human T lymphopoiesis and immune response, and an animal model for studying T lymphotropic viral infections, such as HIV.     

Morphological changes of Babesia gibsoni grown in canine red blood cell-substituted severe combined immune deficiency mice

Canine red blood cell-substituted severe combined immune deficiency (Ca-RBC-SCID) mice were prepared for canine Babesia gibsoni infection. The Ca-RBC-SCID mice infected with B. gibsoni developed a high level of parasitemia, and showed clinical symptoms such as anemia and hemoglobinuria, which are similar to those observed in dogs infected with B. gibsoni. The B. gibsoni parasites grown in Ca-RBC-SCID mice showed marked morphological changes, including a significantly larger size of parasites than those in dogs and abundant RBCs containing 4, 8, 16, and 32 parasites. The multiple infection may have resulted from 1 parasite because the posterior end of each parasite in a multiply infected cell was connected. The parasites grown in SCID mice retained their infectivity and virulence to dogs and their morphology was dramatically restored to the original state when they were returned to dogs.