脊髓灰质炎病毒感染赤麂细胞株的实验研究

脊髓灰质炎病毒的敏感细胞范围一直局限于灵长类动物细胞。用该病毒感染处理非灵长类的赤麂肺二倍体细胞(KIZ-7901),可诱导9.0—14.7%的细胞出现染色体畸变,除见有染色体或单体断裂外,还见有断片、双着丝粒、环、互换、易位和缺失等。也可引致姐妹染色单体交换率(SCE)的显著提高。脊髓灰质炎病毒感染赤麂细胞后,不产生特异的CPE,不明显影响细胞群体的增殖。应用病毒滴定、包涵体检查,间接免疫荧光试验和电镜检查,都可查见细胞内有病毒或其抗原物质存在。这提示脊髓灰质炎病毒在非灵长类的赤麂细胞内呈现非杀细胞性感染。     

麂属(Muntiacus)动物线粒体12SrRNA和细胞色素B基因序列分析及其分子进化关系

对麂属（Muntiacus)中的3种动物;赤麂（M.muntjak)（2n=6♀,7♂）,小麂（M.reevesi)(2n=46）,黑（M.crinifrons(2♀,9♂）线粒体DNA12SrRNA和细胞色素B783bp左右的片段进行序列分析,并根据序列信息建立分子系统树,同时探讨了这3种动物的起源,分类地位及进化关系。     

赤麂、小麂及其F_1杂种的比较细胞遗传学研究

赤麂(Muntiacus muntjak)是脊椎动物中已知染色体数目最少的动物,2n=(?)7,♀6,NF=12。赤麂的同源种或近缘种小麂(M.reevesi)的染色体数为2n=46,NF=46。这两个外部形态十分相似的近缘种,核型却有如此巨大的差别,在哺乳动物核型进化的研究中,仍是一个十分令人迷惑的问题。更使人惊奇的是,这两个核型差别如此明显的物种居然还可以杂交。在上海西郊公园,雄性赤麂和雌性小麂杂交后得到几只第一代杂种。我     

麂属(Muntiacus)动物线粒体12S rRNA、细胞色素b基因和多药耐药基因序列分析及其分子进化关系

对麂属（Muntiacus)中的3种动物：赤麂（M.muntjak)(2n=6♀,7♂）,小麂（M.reevesi)(2n=46),黑麂（M.cri.nifrons)(2n=8♀,9♂）线粒体DNA 12S rRNA和细胞色素b基因784bp左右的片段和核基因－多药耐药基因（multidrug resistance,MDR1)的728bp左右的片段进行了序列分析,并根据序列信息建立了分子系统树,同时探讨了这3种动物的起源,分类地位及进化关系。     

赤麂和小麂♀×赤麂♂的杂种外周淋巴细胞动力学和姐妹染色单体交换率的研究

赤麂及其杂种(赤麂×小麂)外周淋巴细胞在离体培养条件下,培养了24小时均未出现分裂相。到36小时,赤麂只有1.4%而杂种麂已有10.5%的分裂细胞进入第2次分裂。在48小时,赤麂细胞尚未进入第3次分裂,而杂种麂却已有4.7%和0.2%的分裂细胞分别进入第3次和第4次分裂。在72小时,赤麂及其杂种的大多数分裂细胞仍处于第2次分裂阶段,进入第3次和第4次分裂的细胞数量也随之增多。赤麂的姐妹染色单体交换率在48和72小时分别为5.08±0.33/细胞和5.33±0.30/细胞;向杂种麂的姐妹染色单体交换率分别为4.76±0.21/细胞和5.40±0.74/细胞。     

活性氧对大鼠肝卵圆细胞株WB-F344钾通道的作用

用膜片箝技术的细胞贴附式 (cell-attached)观察O2.-对大鼠肝卵圆细胞株WB -F344K 通道活动的影响 ,结果发现 :1)在细胞处于静息状态时 ,在箝制电压为0mV ,每10mV阶跃 ,测试电压分别达±120mV范围内未记录到通道活动。此时 ,小剂量O2.- 也不能激活WB细胞的通道活动。在细胞外液中加入20mmol/LCaCl2 后通道开启 ,记录到小振幅的通道活动 ,它们的电导是9.48±0.93ps(n=4)。此时再用O2.-作用于细胞 ,通道被激活 ,通道电导增大 ,在正测试电压时为15.74±5.46ps(n=8) ,在负测试电压时为48.32±8.67ps(n=6)。通道活动具有外向整流特性。2)胞外加入4 -AP可抑制该通道的活动 ,而SNP则可增强通道的活动。     

麂属(Muntiacus)动物MDR-1基因序列分析及其分子进化关系

对麂属（Muntiacus)中的3种动物：赤麂（M.muntjak)(2n-6♀,7♂）,小麂（M.reevesi)(2n=46),黑麂（M.crinifrons(2n=8♀,9♂）MDR－1基因（multidrug resistance,多药耐药基因）726bp左右的片段进行了序列分析并根据序列信息建立分子系统树,同时探讨了这3种动物的起源,分类地位及进化关系。     

赤麂线粒体全基因组的序列和结构

提取赤麂细胞株总DNA,参照我们实验室已测定的同属动物小麂线粒体全基因组序列设计引物,PCR扩增、测序、拼接,获得赤麂线粒体全基因组序列并进行生物信息学分析。赤麂线粒体全基因组序列全长16354bp。定位了22个tRNA基因、2个rRNA基因、13个蛋白编码基因和1个D-loop区。赤麂与小麂及其它哺乳动物线粒体的基因组结构相同,它们的序列同源性都较高。     

赤麂(Muntiacus muntjak)细胞株的建立及其生物学特性观察

赤麂(Munliacus muntjak)是迄今已知染色体数目最少的脊椎动物(Wurster,D.H.et al.1970),每条染色体都有明显的个体性,用常规染色方法即可清晰无误地一一加以区开,染色体又特别大。因此,这是比较理想的细胞遗传学实验材料。目前,国外已从印度产的成年印度麂(赤麂)的皮肤、肺、肾等组织建立了细胞株(Altman,P.L etal.1976;Brown,J.A et al.1973;Kato,H et al.1974;Yanagychi,N 1979)并广泛应用于辐射细胞遗传学,进化遗传学,遗传毒理学等许多方面的研究,取得了许多有意义的结果。     

埃塞俄比亚芥与诸葛菜属间杂种的基因组原位杂交分析

用幼胚培养方法重新获得的埃塞俄比亚芥(Brassica carinata A.Braun,2n=34)与诸葛菜(Orychophragmus violaceus (L.)O.E.Schulz,2n=24)的属间杂种仍为混倍体(2n=14～34),2n=34细胞的频率最高;绝大多数花粉母细胞(PMCs)表现正常的17个二价体配对和17：17的分离。基因组原位杂交分析结果表明,在所有体细胞和PMCs中不含有整条的诸葛菜染色体,2n=34的体细胞和PMCs中包含了来自黑芥(B．nigra (L．)Koch,2n=16)的16条染色体。这些具有完全或部分埃塞俄比亚芥染色体组成的细胞,可能来源于以前提出的杂种细胞在有丝分裂中完全或部分亲本染色体组分开和染色体复制,并伴随诸葛菜染色体的消除。     

Human telomerase can immortalize Indian muntjac cells

The mechanisms of replicative senescence by telomere shortening are not fully understood. The Indian muntjac has the fewest chromosomes of all mammals, greatly simplifying the analysis of each telomere over time. In this study, telomere shortening was observed throughout the life span of cultured normal muntjac cells by quantitative fluorescence in situ hybridization and terminal restriction fragment analysis. Ectopic expression of the human telomerase catalytic subunit in these cells reconstituted telomerase activity, extended telomere lengths, and immortalized the cells, demonstrating that the Indian muntjac cells can serve as a telomere-based replicative senescence model for human cells. In one strain, two chromosome ends had significantly shorter telomeres than the other ends, which led to a variety of chromosome abnormalities. Near senescence, additional ends became telomere signal free, and chromosome aberrancies increased dramatically. Interstitial telomere sequences coincided with fragile sites, suggesting that these remnants of chromosome fusion events might contribute to genome instability. One SV40-immortalized cell line lacked telomerase, and its genetic instability was corrected by the ectopic expression of telomerase, confirming that too-short telomeres were the source of abnormalities. Indian muntjac cells provide an excellent system for understanding the mechanism of replicative senescence and the role of telomerase in the elongation of individual telomeres.     

Insertion of muntjac gene segment into hamster cells by cell fusion

Indian muntjac diploid cells that have only three pairs of easily discernible large chromosomes were fused with hamster cells deficient in hypoxanthine guanine phosphoribosyltransferase (HGPRT) using polyethylene glycol. Cells that survived in hypoxanthine-aminopterine-thymidine (HAT)-oubaine medium were analyzed. Hybrid cells containing both muntjac and hamster chromosomes in a given cell were not found. Instead, the cells had the same chromosomal sets as those of either parental muntjac or hamster cells. A clonal isolate that had the same chromosomal sets as those of parental hamster cells was analyzed in detail and showed the following characteristics: (1) portions of the survival curve in various concentrations of HAT medium were intermediate between those of parental cells; (2) expressions of both muntjac and hamster antigen(s) were detected by immunofluorescence staining; (3) the mobility of the enzyme HGPRT in gel electrophoresis differed from that of parental hamster or muntjac cells. These results indicate that the clonal isolate (AD202h) is a somatic cell hybrid of hamster and muntjac that contains chromosomal sets of hamster with an inserted segment of the muntjac genome, including HGPRT. The formation of such an unusal hybrid and a possible explanation of transfer of some gene segments in the hybrid cell in this system are discussed.     

Characterization of nuclear compartments identified by ectopic markers in mammalian cells with distinctly different karyotype

The functional organization of chromatin in cell nuclei is a fundamental question in modern cell biology. Individual chromosomes occupy distinct chromosome territories in interphase nuclei. Nuclear bodies localize outside the territories and colocalize with ectopically expressed proteins in a nuclear subcompartment, the interchromosomal domain compartment. In order to investigate the structure of this compartment in mammalian cells with distinctly different karyotypes, we analyzed human HeLa cells (3n+=71 chromosomes) and cells of two closely related muntjac species, the Chinese muntjac (2n=46 chromosomes) and the Indian muntjac (2n=6/7 chromosomes). The distribution of ectopically expressed intermediate filament proteins (vimentin and cytokeratins) engineered to contain a nuclear localization sequence (NLS) and a nuclear particle forming protein (murine Mx1) fused to a yellow fluorescent protein (YFP) was compared. The proteins were predominantly localized in regions with poor DAPI staining independent of the cells karyotype. In contrast to NLS-vimentin, the NLS-modified cytokeratins were also found close to the nuclear periphery. In Indian muntjac cells, NLS-vimentin colocalized with Mx1-YFP as well as the NLS-cytokeratins. Since the distribution of the ectopically expressed protein markers is similar in cells with distinctly different chromosome numbers, the property of the delineated, limited compartment might indeed depend on chromatin organization.     

Karyological characteristics of cell sublines of the kidney of the kangaroo rat and of skin fibroblasts of the Indian muntjac

A study was made of the karyotypic structure of sublines derived from the kangaroo rat's kidney (NBL-3) and skin fibroblasts of the Indian muntjac, available in the cell culture bank of the Institute of Cytology Acad. Sci. USSR. A comparative karyologic analysis was made of subline NBL-3 both contaminated with mycoplasma (NBLK) and decontaminated with antibiotics (NBLD). Authentic differences in cell distribution according to chromosome number in NBLK and NBLD variants were shown. Modal numbers of chromosomes are 11 and 17, respectively. The modal number for the Indian muntjac cell subline (MT) is 9. 60-80% of the cells had an identical karyotype (the main structural variant of the karyotype is MSVK). Using the G-banding technique, all the MSVK variants were shown to display constant karyotypes. In NBLK there are 5 pairs of homologous chromosomes and one metacentric. In NBLD, the number of homologous chromosomes increased in all the groups (hypotriploid karyotype). In subline MT 3 homologous chromosomes were found in groups I and IV, 2 in group III in addition to one X-chromosome. A comparison with the Indian muntjac karyotype showed the absence of marker chromosomes in MT. The analysis of additional SVK shows that the deviations from MSVK are caused mostly by changes in the number of homologous chromosomes within the groups. A study of the frequency of deviations in chromosome numbers observed in the groups from MSVK showed that different chromosomes were involved in karyotypic changes in the same way in the "low-chromosome" variants of NBLK and MT, and in different ways in NBLD. A comparison of the "premycoplasmic" variants of line NBL-3 with NBLK shows no differences in the parameters studied.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative gene mapping in the species Muntiacus muntjac.

An extreme case of chromosomal evolution is presented by the two muntjac species Muntiacus muntjac (Indian muntjac, 2n = 6 [females], 7 [males]) and M. reevesi (Chinese muntjac, 2n = 46). Despite disparate karyotypes, these phenotypically similar species produce viable hybrid offspring, indicating a high degree of DNA-level conservation and genetic relatedness. As a first step toward development of a comparative gene map, several Indian muntjac homologs of known human type I anchor loci were mapped. Using flow-sorted, chromosome-specific Southern hybridization techniques, homologs of the protein kinase C beta polypeptide (PRKCB1) and the DNA repair genes ERCC2 and XRCC1 have been assigned to Indian muntjac chromosome 2. The male-specific ZFY gene was presumptively mapped to Indian muntjac chromosome Y2. Ultimate generation of a comparative physical map of both Indian and Chinese muntjac chromosomes will prove invaluable in the study of mammalian karyotype evolution.     

New evidence for tandem chromosome fusions in the karyotypic evolution of Asian muntjacs

A clone of highly repetitive DNA, designated C5, was isolated from DNA of female Chinese muntjac cells. The nucleotide sequence of this clone is 80%–85% homologous to that of the satellite IA clone and other highly repetitive DNA clones previously obtained from the Indian muntjac. Using C5 as a probe for in situ hybridizations to chromosome preparations of cells of both the Chinese and Indian muntjacs, we were able to show that these repeated sequences occur in centromeric heterochromatin of the chromosomes of both Chinese and indian muntjac species. More significantly, non-random clusters of hybridization signals were detected on the arms of chromosomes of the Indian muntjac. These latter hybridization sites are postulated to be regions of interstitial heterochromatin and could be the remnants of centromeric heterochromatin from ancestral Chinese muntjac chromosomes. Our observations provide new supportive evidence for the tandem chromosome fusion theory that has been proposed for the evolution of the Indian muntjac karyotype.by P.B. Moens     

Compound kinetochores of the Indian muntjac

The chromosomes of the Indian muntjac (Muntiacus muntjak vaginalis) are unique among mammals due to their low diploid number (2N=6, 7) and large size. It has been proposed that the karyotype of this small Asiatic deer evolved from a related deer the Chinese muntjac (Muntiacus reevesi) with a diploid chromosome number of 2n= 46 consisting of small telocentric chromosomes. In this study we utilized a kinetochore-specific antiserum derived from human patients with the autoimmune disease scleroderma CREST as an immunofluorescent probe to examine kinetochores of the two muntjac species. Since CREST antiserum binds to kinetochores of mitotic chromosomes as well as prekinetochores in interphase nuclei, it was possible to identify and compare kinetochore morphology throughout the cell cycle. Our observations indicated that the kinetochores of the Indian muntjac are composed of a linear beadlike array of smaller subunits that become revealed during interphase. The kinetochores of the Chinese muntjac consisted of minute fluorescent dots located at the tips of the 46 telocentric chromosomes. During interphase, however, the kinetochores of the Chinese muntjac clustered into small aggregates reminiscent of the beadlike arrays seen in the Indian muntjac. Morphometric measurements of fluorescence indicated an equivalent amount of stained material in the two species. Our observations indicate that the kinetochores of the Indian muntjac are compound structures composed of linear arrays of smaller units the size of the individual kinetochores seen on metaphase chromosomes of the Chinese muntjac. Our study supports the notion that the kinetochores of the Indian muntjac evolved by linear fusion of unit kinetochores of the Chinese muntjac. Moreover, it is concluded that the evolution of compound kinetochores may have been facilitated by the nonrandom aggregation of interphase kinetochores in the nuclei of the ancestral species.     

Comparative sequence analyses reveal sites of ancestral chromosomal fusions in the Indian muntjac genome

Background

Indian muntjac (Muntiacus muntjak vaginalis) has an extreme mammalian karyotype, with only six and seven chromosomes in the female and male, respectively. Chinese muntjac (Muntiacus reevesi) has a more typical mammalian karyotype, with 46 chromosomes in both sexes. Despite this disparity, the two muntjac species are morphologically similar and can even interbreed to produce viable (albeit sterile) offspring. Previous studies have suggested that a series of telocentric chromosome fusion events involving telomeric and/or satellite repeats led to the extant Indian muntjac karyotype.

Results

We used a comparative mapping and sequencing approach to characterize the sites of ancestral chromosomal fusions in the Indian muntjac genome. Specifically, we screened an Indian muntjac bacterial artificial-chromosome library with a telomere repeat-specific probe. Isolated clones found by fluorescence in situ hybridization to map to interstitial regions on Indian muntjac chromosomes were further characterized, with a subset then subjected to shotgun sequencing. Subsequently, we isolated and sequenced overlapping clones extending from the ends of some of these initial clones; we also generated orthologous sequence from isolated Chinese muntjac clones. The generated Indian muntjac sequence has been analyzed for the juxtaposition of telomeric and satellite repeats and for synteny relationships relative to other mammalian genomes, including the Chinese muntjac.

Conclusions

The generated sequence data and comparative analyses provide a detailed genomic context for seven ancestral chromosome fusion sites in the Indian muntjac genome, which further supports the telocentric fusion model for the events leading to the unusual karyotypic differences among muntjac species.     

Defective post-replication recovery and u.v. sensitivity in a simian virus 40-transformed Indian muntjac cell line

The responses to u.v. of two cell lines derived from the Indian muntjac are described. The u.v. sensitivity of the diploid cell falls within the range of most normal mammalian cells while the other, a heteroploid cell, transformed by SV40, is much more sensitive to killing. This hypersensitivity cannot be explained by defective excision repair: the two cell types are indistinguishable in this activity as judged by inhibitor-associated DNA break accumulation and unscheduled DNA synthesis. Rather, the SV40 transformed cells have a pronounced inability to recover normal DNA replication after u.v. These cells are, therefore, defective in a post-replication recovery mechanism and in this respect resemble the behaviour of the variant form of xeroderma pigmentosum. Their limited ability to recover normal levels of RNA synthesis after u.v. hints at the complexity of the phenotype.     

Morphological and cytochemical characteristics of human cells transformed and made malignant by Rous and polyoma viruses]

In cells of human embryo skin--muscle tissue transformed by the Rouse sarcoma virus (23rd cell line) and polyoma virus (P-2 cell line), the mitotic activity was 48 0/00 for 23rd line, 51 0/00 for P-2 line as against 28 0/00 in the control cells. The transformed cells possessed greater amounts of RNA and DNA and protein--bound SH-groups, different forms of glycogen deposits, as well as higher acid phosphatase enzyme activities; there was practically no difference in acid mucopolysaccharide content or NAD-H2-diaphorase and succinate dehydrogenase activities.