用于肝脏疾病研究的人源化小鼠模型概述

肝脏疾病是危害人类健康的重要疾病之一,合适的小动物模型的缺乏在很大程度上制约了肝脏疾病的相关研究。人源化小鼠作为重要动物模型之一,在肝脏疾病的研究中有巨大的应用价值。本文对早期的uPA小鼠、FAH小鼠、TK-NOG小鼠和近年来的AFC8小鼠等几种应用较为广泛且有代表性的人源化小鼠模型及其在肝脏疾病研究中的应用进行了对比分析,阐述了它们各自的模型原理和优缺点,以期对人源化小鼠应用于人类肝脏疾病的研究具有较为直观的认识。     

人干细胞实验动物嵌合体模型的研究进展

动物模型是疾病研究、发病机制、药物治疗的必要工具,目前一些困扰人类健康的重大疾病如艾滋病、乙型肝炎等因为还没有能反映人类疾病发病机理的理想动物模型。人干细胞是能在体外长期培养的、高度未分化的全能细胞系,亚全能细胞系和分化的干细胞等。如果能将人的干细胞成功移植入实验动物体内形成人源化嵌合体动物,有希望为艾滋病、肝炎等的研究制备适当的模型。人类干细胞在动物中的移植研究中主要的实验动物是绵羊,小鼠等,本文介绍了人干细胞在动物体内移植的研究进展。     

用于病毒研究的人源化小鼠研究进展

人源化小鼠从起初的人-鼠嵌合体到目前具有人体免疫活性的模型不断演进,已用于人免疫缺陷病毒、EB病毒、丙型肝炎病毒和登革病毒等病原体的感染、发病机制和防治的研究,取得了很大进展。我们简要介绍几种有代表性的人源化小鼠模型及其在病毒研究中的应用。     

基于实时荧光PCR定量检测肉制品猪源性成分方法的建立

为了建立肉制品中猪源性成分检测的PCR方法,以猪线粒体细胞色素b(cytochrome b,Cyt b)为目的基因,设计猪特异性PCR引物;以猪、牛、羊、鸡及鸭DNA和不同稀释浓度猪DNA进行Real-time PCR反应,证明了该引物扩增具有物种特异性,检测低限可达5×10-5 ng/μL;设计内参基因β-actin通用引物,以猪源性成分含量0%~100%的混合肉样DNA为模板扩增,建立标准曲线,2-△△Ct值与猪源性成分含量有良好线性关系(R2=0.991 4);对猪源性成分含量0%~75%的混合肉样检测,回收率为99.85%~102.60%。应用建立的PCR方法检测了市售的6种品牌火腿肠,标识为清真食品的5种均未检测到猪源性成分,未标识清真食品的猪源性成分含量为12.70%。建立的实时荧光PCR检测方法操作简便、特异性强、所得数据可靠,为肉制品猪源性成分检测提供了新的手段。     

运用基因芯片技术检测牛、山羊、猪和鸡源性成分

本研究通过对脊椎动物分子标记基因进行序列分析,最终选择线粒体DNA(mtDNA)16S rRNA基因为目标基因,利用一对通用引物,在该引物扩增区间设计了4条特异性基因芯片检测探针及2条质控探针用于对牛、山羊、猪、鸡等4种动物源性成分进行检测。通过对PCR扩增体系及杂交体系的优化,该检测方法能实现对上述4种动物源性成分同时进行快速、准确地检测,具有很好的特异性,灵敏度均达到1pg,最终建立了这4种动物源性基因芯片检测方法。该基因芯片检测技术将为我国进出口饲料中的动物源性成分的鉴别提供新的检测方法和技术支持。     

人源化鼠嵌合肝动物模型研究进展

动物模型是人类疾病研究、发病机制、药物研发的重要工具,对于困扰人类健康的肝脏疾病还没有理想的动物模型能有效地反映出人类疾病发病的机制。建立人源化鼠嵌合肝动物模型,对于研究人类肝脏疾病的发病机制、疫苗和药物的研发及疾病的诊治等方面都具有十分广阔的应用前景。     

用于病毒研究的人源化小鼠研究进展简

人源化小鼠从起初的入-鼠嵌合体到目前具有人体免疫活性的模型不断演进,已用于人免疫缺陷病毒、EB病毒、丙型肝炎病毒和登革病毒等病原体的感染、发病机制和防治的研究,取得了很大进展。我们简要介绍几种有代表性的人源化小鼠模型及其在病毒研究中的应用。     

多重实时荧光PCR检测牛、山羊和绵羊源性成分

根据牛、山羊和绵羊线粒体细胞色素b基因序列, 设计特异性引物和以不同荧光素标记的Taqman探针。通过对PCR反应体系和反应条件的优化筛选, 建立能同时鉴别牛、山羊和绵羊源性成分的多重实时荧光PCR方法。采用本文方法与国标GB/T 20190-2006方法分别对17种不同源性动物DNA和200份不同来源样品DNA进行牛羊源性成分检测, 数据显示两者检测结果符合率达100%, 特异性相当。与国标方法相比, 本试验方法不需电泳、酶切和测序, 即可在一个PCR反应中同时鉴别检测牛、山羊和绵羊3种源性成分, 检测效率提高近3倍; 灵敏度更高, 比国标方法灵敏10倍; 适用性更广, 除了饲料, 还适用于肉品、奶品、生皮和动物油脂等动物产品的牛羊源性成分检测。     

肿瘤坏死因子受体超家族成员4(TNFRSF4)敲除和人源化小鼠模型的建立

目的建立肿瘤坏死因子受体超家族成员4(TNFRSF4)基因人源化小鼠模型,同时建立TNFRSF4基因敲除小鼠模型,为针对TNFRSF4靶点的肿瘤治疗性抗体研发和筛选提供有效的小鼠模型,并为研究TNFRSF4在免疫过程中的作用机制提供小鼠模型。方法利用CRISPR/Cas9技术,建立TNFRSF4基因人源化和敲除小鼠模型,利用PCR、RT-PCR、免疫组织化学、流式细胞术等方法鉴定及比较分析人源化小鼠、敲除小鼠和野生型小鼠的差异。结果获得表达人源TNFRSF4基因小鼠和TNFRSF4基因敲除小鼠。在TNFRSF4人源化小鼠中稳定表达人源TNFRSF4,未检测到小鼠TNFRSF4表达。在TNFRSF4敲除小鼠中未检测到TNFRSF4表达。TNFRSF4人源化及敲除小鼠出生后6个月内均正常存活,组织病理学表型及免疫系统未见明显异常。结论利用CRISPR/Cas9技术构建TNFRSF4人源化小鼠及敲除小鼠,可用于筛选及评估与TNFRSF4基因相关的治疗性抗体及药物或研究TNFRSF4在免疫过程中作用机制。     

免疫系统人源化小鼠模型构建技术探讨

探讨免疫系统人源化小鼠模型构建技术的方法和技巧,能够提高免疫系统人源化小鼠模型构建的成功率,并为后续的肿瘤免疫治疗药物研发提供临床前动物模型。利用不同移植数量和供体的HuPB-MNC细胞尾静脉注射重度免疫缺陷小鼠NCG,建立免疫系统人源化小鼠模型。每周观察2次,并记录小鼠体重及死亡情况;实验第7、14、21、28和35天眼眶静脉丛试血,流式细胞术监测NCG小鼠外周血中人CD45⁺ T细胞的重建水平。NCG小鼠外周血中人CD45⁺ T细胞水平随注射后时间逐渐升高,约在3~4周达到25%以上。研究结果表明,免疫系统人源化小鼠模型构建应该从构建方法、免疫缺陷小鼠品系、性别和饲养、免疫细胞的供体和数量及细胞状态等各个方面进行考虑,通过采用多种供体克服差异性,优化肿瘤模型和免疫细胞供体联合接种方案最大化利用窗口期等策略提高模型构建成功率及应用转化率,进一步完善实验室免疫系统人源化小鼠模型构建方法,以期为肿瘤免疫疗法提供更有利的药物研发工具。     

Human hepatocytes in mice receiving pre-immune injection with human cord blood cells

It is well established that certain subpopulations of human adult stem cells can generate hepatocyte-like cells when transplanted into adult immunosuppressed mice. In the present study, we wanted to explore whether xeno-transplantation of human cord blood CD34(+) (hCBCD34(+)) cells during pre-immune stages of development in immunocompetent mice might also lead to human-mouse liver chimerism. Freshly isolated hCBCD34(+) cells were xeno-transplanted into non-immunosuppressed mice by both intra-blastocyst and intra-fetal injections. One and four weeks after birth, immunostaining for different human-specific hepatocyte markers: human hepatocyte-specific antigen, human serum albumin, and human alpha-1-antitrypsin indicated the presence of human hepatocyte-like cells in the livers of transplanted animals. Detection of human albumin mRNA further corroborated the development of pre-immune human-mouse chimeras. The current report, besides providing new evidence of the potential of hCBCD34(+) cells to generate human hepatocyte-like cells, suggests novel strategies for generating immunocompetent mice harboring humanized liver.     

Human hepatocytes in mice receiving pre-immune injection with human cord blood cells

It is well established that certain subpopulations of human adult stem cells can generate hepatocyte-like cells when transplanted into adult immunosuppressed mice. In the present study, we wanted to explore whether xeno-transplantation of human cord blood CD34⁺ (hCBCD34⁺) cells during pre-immune stages of development in immunocompetent mice might also lead to human-mouse liver chimerism. Freshly isolated hCBCD34⁺ cells were xeno-transplanted into non-immunosuppressed mice by both intra-blastocyst and intra-fetal injections. One and four weeks after birth, immunostaining for different human-specific hepatocyte markers: human hepatocyte-specific antigen, human serum albumin, and human α-1-antitrypsin indicated the presence of human hepatocyte-like cells in the livers of transplanted animals. Detection of human albumin mRNA further corroborated the development of pre-immune human-mouse chimeras. The current report, besides providing new evidence of the potential of hCBCD34⁺ cells to generate human hepatocyte-like cells, suggests novel strategies for generating immunocompetent mice harboring humanized liver.     

Selective overproduction of human dihydrofolate reductase in a methotrexate-resistant human-mouse somatic cell hybrid

The development of methotrexate (MTX) resistance in cultured cells results in increased levels of the drug's target enzyme dihydrofolate reductase (DHFR). Stepwise-selected MTX-resistant sublines originating from an MTX-sensitive human-mouse hybrid expressed elevated DHFR levels and human-DHFR specific gene sequence amplification. By high resolution two-dimensional polyacrylamide gradient electrophoresis, human DHFR was shown to be selectively overproduced in VB2a-100 MTX-resistant cells whereas mouse DHFR protein "spots" present in MTX-sensitive parental hybrid were absent in these cells exhibiting 100 microM MTX resistance. These findings and those in a parallel study indicate that concurrent with overproduction of human DHFR and amplification DHFR sequences in VB2a-100, a loss of mouse-specific DHFR gene sequences occurred.     

HIV-1-induced cell fusion is mediated by multiple regions within both the viral envelope and the CCR-5 co-receptor.

Although the human hCCR-5 chemokine receptor can serve as a co-receptor for both M-tropic (ADA and BaL) and dual-tropic (89.6) strains of human immunodeficiency virus type 1 (HIV-1), the closely related mouse mCCR-5 homolog is inactive. We used chimeric hCCR-5-mCCR-5 receptor molecules to examine the functional importance of the three extracellular domains of hCCR-5 that differ in sequence from their mCCR-5 equivalents. While this analysis revealed that all three of these extracellular domains could participate in the functional interaction with HIV-1 envelope, clear differences were observed when different HIV-1 strains were analyzed. Thus, while the ADA HIV-1 isolate could effectively utilize chimeric human-mouse CCR-5 chimeras containing any single human extracellular domain, the BaL isolate required any two human extracellular sequences while the 89.6 isolate would only interact effectively with chimeras containing all three human extracellular sequences. Further analysis using hybrid HIV-1 envelope proteins showed that the difference in co-receptor specificity displayed by the ADA and BaL isolates was due partly to a single amino acid change in the V3 loop, although this interaction was clearly also modulated by other envelope domains. Overall, these data indicate that the interaction between HIV-1 envelope and CCR-5 is not only complex but also subject to marked, HIV-1 isolate-dependent variation.     

Nuclear counterparts of the cytoplasmic mitochondrial 12S rRNA gene: A problem of ancient DNA and molecular phylogenies

Monkey mummy bones and teeth originating from the North Saqqara Baboon Galleries (Egypt), soft tissue from a mummified baboon in a museum collection, and nineteenth/twentieth-century skin fragments from mangabeys were used for DNA extraction and PCR amplification of part of the mitochondrial 12S rRNA gene. Sequences aligning with the 12S rRNA gene were recovered but were only distantly related to contemporary monkey mitochondrial 12S rRNA sequences. However, many of these sequences were identical or closely related to human nuclear DNA sequences resembling mitochondrial 12S rRNA (isolated from a cell line depleted in mitochondria) and therefore have to be considered contamination. Subsequently in a separate study we were able to recover genuine mitochondrial 12S rRNA sequences from many extant species of nonhuman Old World primates and sequences closely resembling the human nuclear integrations. Analysis of all sequences by the neighbor-joining (NJ) method indicated that mitochondrial DNA sequences and their nuclear counterparts can be divided into two distinct clusters. One cluster contained all temporary cytoplasmic mitochondrial DNA sequences and approximately half of the monkey nuclear mitochondriallike sequences. A second cluster contained most human nuclear sequences and the other half of monkey nuclear sequences with a separate branch leading to human and gorilla mitochondrial and nuclear sequences. Sequences recovered from ancient materials were equally divided between the two clusters. These results constitute a warning for when working with ancient DNA or performing phylogenetic analysis using mitochondrial DNA as a target sequence: Nuclear counterparts of mitochondrial genes may lead to faulty interpretation of results.Correspondence to: A.C. van der Kuyl     

Rethinking the oversight conditions of human–animal chimera research

New discoveries are improving the odds of human cells surviving in host animals, prompting regulatory and funding agencies to issue calls for additional layers of ethical oversight for certain types of human–animal chimeras. Of interest are research proposals involving chimeric animals with humanized brains. But what is motivating the demand for additional oversight? I locate two, not obviously compatible, motivations, each of which provides the justificatory basis for paying special attention to different sets of human–animal chimeras. Surprisingly, the sets of animals that actually get flagged for special scrutiny by research and funding guidelines do not correlate with either of the sets of animals that arise when we think about what is motivating additional oversight. What this shows is that existing research policies and funding guidelines are disconnected from their motivation: the rationale for flagging certain types of human–animal chimeras as requiring special oversight is ignored in execution.     

Evolution, expression, and chromosomal location of a novel receptor tyrosine kinase gene, eph.

Partial sequence analysis of the genomic eph locus revealed that the splicing points of kinase domain-encoding exons were completely distinct from those of the other protein tyrosine kinase members reported, suggesting that this is the earliest evolutionary split within this family. In Northern (RNA) blot analysis, the eph gene was expressed in liver, lung, kidney, and testis of rat, and screening of 25 human cancers of various cell types showed preferential expression in cells of epithelial origin. Overexpression of eph mRNA was found in a hepatoma and a lung cancer without gene amplification. Comparison of cDNA sequences derived from a normal liver and a hepatoma that overproduces eph mRNA demonstrated that two of them were completely identical throughout the transmembrane to the carboxy-terminal portions. Southern blot analysis of DNAs from human-mouse hybrid clones with an eph probe showed that this gene was present on human chromosome 7.     

Identification of a novel mitochondrial genome type and development of molecular markers for cytoplasm classification in radish (<Emphasis Type="Italic">Raphanus sativus</Emphasis> L.)

Plant mitochondrial genomes have complex configurations resulting from the multipartite structures and highly rearranged substoichiometric molecules created by repetitive sequences. To expedite the reliable classification of the diverse radish (Raphanus sativus L.) cytoplasmic types, we have developed consistent molecular markers within their complex mitochondrial genomes. orf138, a gene responsible for Ogura male-sterility, was detected in normal cultivars in the form of low-copy-number substoichiometric molecules. In addition to the dominant orf138-atp8 Ogura mitochondrial DNA (mtDNA) organization, three novel substoichiometric organizations linked to the atp8 gene were identified in this study. PCR amplification profiles of seven atp8- and atp6-linked sequences were divided into three groups. Interestingly, the normal cytoplasm type, which had previously been considered a single group, showed two patterns by PCR amplification. The most prominent difference between the two normal mtDNAs was size variation within four short-repeat sequences linked to the atp6 gene. This variation appeared to be the result of a double crossover, mediated by these homologous, short-repeat sequences. Specific PCR amplification profiles reflecting the stoichiometry of different mtDNA fragments were conserved within cultivars and across generations. Therefore, the specific sequences detected in these profiles were used as molecular markers for the classification of diverse radish germplasm. Using this classification system, a total of 90 radish cultivars, or accessions, were successfully assigned to three different mitotypes.     

GENETIC CONTROL OF MITOCHONDRIAL THYMIDINE KINASE IN HUMAN-MOUSE AND MONKEY-MOUSE SOMATIC CELL HYBRIDS

Distinctive thymidine (dT) kinase molecular forms are present in mouse, human, and monkey mitochondria. Disk polyacrylamide gel electrophoresis (disk PAGE) analyses have shown that the mitochondrial-specific dT kinases differ from cytosol dT kinases in relative electrophoretic mobilities (Rm). Furthermore, the mouse mitochondrial dT kinase differs in Rm value from primate mitochondrial dT kinases. The mouse and primate cytosol dT kinases can also be distinguished. Disk PAGE analyses have been carried out on the cytosol and mitochondrial dT kinases of human-mouse (WIL-8) and monkey-mouse (mK·CV^III) somatic cell hybrids in order to learn whether the mitochondria of the hybrid cells contained murine mitochondrial-specific, primate mitochondrial-specific, or both dT kinases. WIL-8 cells were derived from cytosol dT kinase-negative, mitochondrial dT kinase-positive mouse fibro blasts and from cytosol dT kinase-positive, mitochondrial dT kinase-positive human embryonic lung cells; they contained mostly mouse chromosomes and a few human chromosomes, including the determinant for human cytosol dT kinase. The mK·CV^III cells were derived from cytosol dT kinase-negative, mitochondrial dT kinase-positive mouse kidney cells and from cytosol dT kinase-positive, mitochondrial dT kinase-positive monkey kidney cells; they contained mostly mouse chromosomes and a few monkey chromosomes, including the determinant for monkey cytosol dT kinase. Disk PAGE analyses demonstrated that the mitochondria of human-mouse and monkey-mouse somatic cell hybrids contained the mouse-specific mitochondrial dT kinase but not the human- or monkey-specific mitochondrial dT kinase. These findings suggest that primate cytosol and mitochondrial thymidine kinase genes are coded on different chromosomes.