4种小鼠的寒、热体质研究

[目的]研究4种品系小鼠的寒、热体质。[方法]8~9周龄昆明、BALB/c、C57BL/6J、ICR小鼠,以及4~5周龄昆明小鼠,同步系统检测其生物学特性,然后以统一的评价标准评价4种品系小鼠的寒、热体质。并对BALB/c小鼠给予参桂理中丸和利血平做药物反证。[结果]①4~5周龄昆明小鼠与8~9周龄昆明小鼠比较体质明显偏热;②BALB/c小鼠与C57BL/6J小鼠比较体质偏寒;③8~9周龄雄性BALB/c小鼠、雄性和雌性C57BL/6J小鼠与8~9周龄相应性别昆明小鼠比较体质无明显差异;8~9周龄雌性BALB/c小鼠与8~9周龄雌性昆明小鼠比较体质偏寒;④8~9周龄ICR小鼠与8~9周龄BALB/c小鼠、C57BL/6J小鼠比较体质偏热;8~9周龄雄性ICR小鼠与8~9周龄雄性昆明小鼠比较体质偏热。[结论]4种品系小鼠存在寒、热体质差异。     

抗H-Y抗原单克隆抗体的研究

H-Y抗原是由Y染色体编码的、雄性动物特有的组织相容性抗原,分布在细胞膜表面,利用抗H-Y抗体可以鉴别或杀伤早期的雄性胚胎,从而达到控制动物性别的目的。但是,用常规方法获得的H-Y抗体,产量很低,效价不高,无法大量应用。为此,我们采用单克隆抗体技术解决这一问题。 用雄性C57小鼠的脾细胞免疫雌性C57小鼠,经加强免疫后,取免疫雌鼠的脾细胞与骨     

间接免疫荧光法鉴别小鼠早期胚胎性别的研究

以间接免疫荧光法检测昆明系小鼠早期胚胎雄性特异性H—Y抗原的表达。结果表明:54%的胚胎为H—Y阳性(雄性);46%为H—Y阴性(雌性)。经与昆明系小鼠的自然性比率(♂:52%;♀:48%)比较,两者无显著性差异。 经细胞遗传学方法确证,以免疫荧光法鉴别的胚胎性别,雄性的鉴别准确率为75.50%;雌性为82.97%。 本文还就影响鉴别准确率的若干因素以及本方法在生产中的应用前景等问题进行了分析讨论。     

小鼠早期胚胎性别鉴定的研究

用改进的细胞遗传学方法制备染色体标本,鉴定了小鼠晚期桑椹胚(晚桑)、囊胚和扩展囊胚(扩囊)的性别。在实验中,利用小鼠早期胚胎染色体标本制备的理想实验参数,鉴定了242枚小鼠晚桑、囊胚和扩囊的性别,性别鉴定成功率分别为80.4％、99.0％和94.5％。以细胞遗传学方法鉴定小鼠早期胚胎性别的结果为标准,得出用间接免疫荧光法和PCR(聚合酶链反应)扩增SRY(y染色体的性别决定期)部分序列法分别鉴定100枚和26枚小鼠胚胎性别的准确率相应地为74.0％和92.3％。     

大鼠Y染色体探针的制备与鉴定

目的:研究制备地高辛标记的大鼠性别决定基因Y区(Y染色体,SRY)探针,用于检测雄性大鼠来源的细胞在雌性受鼠体内的SRY基因表达情况.方法:按已知的雄性大鼠Y染色体上性别决定基因(SRY)的序列,请上海博亚公司合成oligoDNA,采用PCR技术连接并扩增,地高辛标记的方法制备基因探针.以雌性大鼠为对照,原位杂交法检测大鼠肾组织切片Y染色体阳性细胞情况.结果:用原位杂交法证实在雄性大鼠肾脏内有SRY表达,而雌性大鼠肾脏无Y染色体阳性细胞,证实这种探针具有较高的敏感性和特异性.结论:大鼠性别决定基因SRY探针的制备成功,为进一步研究异体雄性大鼠细胞移植后的分布和表达提供了实验基础.     

一种新的近交系实验动物遗传监测方法及小鼠性别相关RAPD标记的发现

我们用21个10 bp的随机短引物对来自昆明、成都、上海、北京四个地方的BALB/c小鼠以及C57BL小鼠、昆明种小白鼠进行了随机扩增多态DNA(RAPD)分析,发现13个引物的扩增产物在BALB/c小鼠和C 57 BL小鼠中有差异,8个引物的扩增产物在BALB/c小鼠和昆明种小白鼠之间不同.在四个地方的BALB/c小鼠中,成都、上海、北京的BALB/c小鼠其遗传背景均一,而来自昆明的BALB/c小鼠中,有2只的4个引物的扩增产物不同于其它的BALB/c小鼠,表明这两只BALB/c小鼠可能曾发生过某种程度的遗传改变或污染。实验结果显示RAPD方法是一种有效的近交系实验动物遗传监测手段。实验中一个有趣的结果是,在OPG 2、OPE 4、OPE 9的扩增产物中,发现了严格的性别依赖的PAPD标记。OPE 9扩增产物中,凡雄性个体都有一条0.88 kb的标记.OPG 2、OPE 4则在所有的雄性个体中多扩增出一条约1.2 kb的带。通过交叉PCR扩增和斑点杂交证明OPG 2、OPE 4 得到的雄性特异性RAPD标记虽分子大小一致,但不具同源性。这些性别相关RAPD标记的染色体定位和性质分析正在进一步进行中.     

两温度梯度多重PCR鉴别牛早期胚胎性别的技术

稳定、可靠和快速的牛胚胎性别鉴定方法在生产应用中具有重要意义.通过两温度梯度PCR方法对牛基因组、克隆胚胎、胚胎样品进行性别鉴别实验研究,建立了稳定、简便、快速的牛早期胚胎性别鉴别两温度梯度PCR方法,鉴定时间仅为57分钟.采用两温度梯度PCR方法对30枚奶牛胚胎进行了早期性别鉴别,并将鉴别的15枚胚胎(11枚为雌性,4枚为雄性)移植到同期处理的15头受体母牛体内.60天后妊娠检查,有7个受体成功受孕,5头受体怀孕晚期流产,流产犊牛全部为母犊.结果产下1公1母两头犊牛,流产个体与出生个体的性别与PCR鉴别结果完全相符.     

两温度梯度多重PCR鉴别牛早期胚胎性别的技术研究

稳定、可靠和快速的牛胚胎性别鉴定方法在生产应用中具有重要意义。通过两温度梯度PCR方法对牛基因组、克隆胚胎、胚胎样品进行性别鉴别实验研究,建立了稳定、简便、快速的牛早期胚胎性别鉴别两温度梯度PCR方法,鉴定时间仅为57分钟。采用两温度梯度PCR方法对30枚奶牛胚胎进行了早期性别鉴别,并将鉴别的15枚胚胎（11枚为雌性,4枚为雄性）移植到同期处理的15头受体母牛体内。60天后妊娠检查,有7个受体成功受孕,5头受体怀孕晚期流产,流产犊牛全部为母犊。结果产下1公1母两头犊牛,流产个体与出生个体的性别与PCR鉴别结果完全相符。      

鉴定小鼠胚胎性别的染色体标本制作方法研究

通过制备７２６４枚小鼠胚胎的染色体标本并鉴定其性别的试验,获得了理想的实验参数。采用理想的实验参数,制作和鉴定了２４２枚小鼠晚期桑椹胚、囊胚和扩展整胚的染色体标本及其性别,性别鉴定成功率分别为８０．４％、９９．０％和９４．５％。     

双重套式PCR对不同取样胚胎性别鉴定灵敏度测试

目的:测定双重套式PCR微量扩增体系的灵敏度,为附植前遗传学诊断 (PGD)、家畜胚胎性别鉴定等提供技术保障。方法:以桑椹胚卵裂球为模板进行扩增,建立昆明白小鼠特异的SRY ZFX双重套式PCR性别鉴定体系。按卵裂球数量的不同分为五组,对应的卵裂球个数分别为 1、2、3、4、5及以上。根据有效扩增结果得出双重套式PCR的灵敏度。结果:第 1组 (卵裂球个数为 1 ),有效检出率为 85 % ( 34 /40 ),污染率为 7 5 % ( 3 /40 ),漏检率为 7 .5 % ( 3 /40 )。随着卵裂球个数的增多,有效检出率逐渐升高,而污染率和漏检率则呈逐渐下降趋势。第 5组 (卵裂球达到 5及以上 ),有效检出率达到 1 0 0 %,漏检率为 0。对于第 2、3、4、5组而言,有效检出率及漏检率各组间并无显著差异 (P >0 . 0 5 );而第一组与其它各组间,有效检出率及漏检率存在显著差异 (P <0 .0 5 )。结论:双重套式PCR可以有效扩增基因组DNA量约为 1 2pg的模板,且扩增片段为单拷贝片段。     

Semen quality parameters and embryo lethality in mice deficient for Trp53 protein

Trp53 is a protein which is able to control semen parameters in mice, but the extent of that control depends on the genetic background of the mouse strain. Males from C57BL/6Kw, 129/Sv, C57BL×129 -p53+/+ (wild type controls) and C57BL×129-p53-/- (mutants) strains were used in the study, and histology and light microscopy were applied to evaluate the influence of genetic background and Trp53 (p53) genotype on testes morphology and semen quality in male mice. We showed that sperm head morphology, maturity and tail membrane integrity were controlled only by the genetic background of C57BL/6Kw and 129/Sv males, while testes weight and sperm concentration depended on both the genetic background and p53 genotype. Cell accumulation in seminiferous tubules may be responsible for heavier testes of p53-deficient males. In addition, to examine the effect of sex and p53 genotype on embryo lethality, pairs of control (C57BL×129-p53+/+) and heterozygous (C57BL×129-p53+/-) mice were examined. Before day 7 post coitum (dpc), female and male embryos were equally resorbed in both crosses types. After 7 dpc, preferential female embryo lethality in the heterozygote pairs was responsible for the skewed sex ratio in their progeny. Also, mutant female and male newborns were underrepresented in the litters of the heterozygous breeding pairs.     

Developmental arrest of fertilized eggs from the B6.YDOM sex-reversed female mouse

When the Y chromosome of a Mus musculus domesticus mouse strain is placed onto the C57BL/6J (B6) inbred background, the XY progeny develop ovaries or ovotestes but never normal testes during fetal life. While some of the hermaphroditic males become fertile, none of the XY females produces litters. Here, we examined the fertility and development of oocytes derived from the XY female mouse. With or without preceding injection of gonadotropins, female mice were mated with normal B6 males, and their embryos were recovered at various developmental stages. In vitro fertilization was performed with the eggs recovered from the oviduct after treatment with go-nadotropins. Development of embryos was examined by both light and electron microscopy. The results indicate that the oocytes released from the B6.Y^DOM ovary were efficiently fertilized and often initiated the first cell cleavage, but all embryos died during early preimplantation periods. Even when oocytes were fertilized in vitro, minimizing their exposure to the XY oviduct/uterus environment, most embryos died at the 1- or 2-cell stage. A few exceptional embryos reached the 4- or 8-cell stage, but abnormalities were evident in both nuclear and cytoplasmic structures of all embryos. After cleavage, neighbouring blastomeres were only loosely associated, and microvilli were abundant at the intercellular interfaces. We postulate that oocytes of the B.6.Y^DOM female mouse become defective during XY ovarian differentiation, and, hence, fail to proceed through normal embryonic development. © 1994 Wiley-Liss, Inc.     

Transplantation of male pronucleus derived from in vitro fertilization of enucleated oocyte into parthenogenetically activated oocyte results in live offspring in mouse

In this study, inter-strain reconstructed embryos were produced by combining the female pronucleus of Kunming mouse (white) with male pronucleus of C57BL/6 strain (black). Metaphase II (MII) oocytes of Kunming mouse were enucleated and the zona pellucida was removed. Then, the enucleated oocytes were inseminated by capacitated sperm of C57BL/6 mouse in vitro. At the same time, MII oocytes of Kunming mouse were artificially activated using strontium chloride solution, which did not contain cytochalasin B. Finally, we removed the male pronucleus derived from C57BL/6 sperm and injected it into a parthenogenetically activated one-pronucleus oocyte by micromanipulation. The reconstructed 2-cell embryos were transplanted into the oviducts of 22 foster mother mice, each receiving about 20 embryos. In the end, seven healthy and live pups were born from one recipient.     

A Repeated Segment on the Mouse Y Chromosome Is Composed of Retroviral-Related, Y-Enriched and Y-Specific Sequences

We report the isolation and characterization of two recombinant clones containing DNA derived from the Y chromosome of the C57BL/10 inbred mouse strain. Both clones were isolated from a lambda phage library derived from a partial EcoRI digest of C57BL/10 male DNA using the murine retrovirus M720. Characterization of these clones showed they were derived from a repeated segment present on the C57BL/10J Y chromosome that contains sequences found elsewhere in the genome. In addition, one clone contained a sequence, designated YB10, that is unique to the Y chromosome and present in approximately 500 copies on the C57BL/10J Y chromosome. Analysis of Southern blots containing DNAs prepared from females and males of representative species from four subgenera of Mus probed with pYB10 and the 3'LTR from one of the Y-associated retroviruses (MuRVY) revealed that, with the exception of a single fragment observed in both female and male DNA of Mus saxicola, hybridization to pYB10 was observed only to male DNA of the species Mus spretus, Mus hortulanus, Mus musculus, Mus domesticus and Mus abbotti. In addition, the pattern and intensity of hybridization to YB10 and the MuRVY-LTR indicated that sequence of divergence was followed by amplification of Y chromosome sequences containing YB10 and MuRVY. The divergence and amplification occurred separately in each of the ancestral lineages leading to M. spretus, M. hortulanus, M. abbotti, M. musculus and M. domesticus. We suggest that acquisition and amplification of DNA sequences by the mammalian Y chromosome has contributed to its evolution and may imply that the mammalian Y chromosome is evolving at a faster rate than the rest of the genome.     

Sexing of mouse preimplantation embryos by detection of Y chromosome-specific sequences using polymerase chain reaction.

Detection of genes known to be present on the mammalian Y chromosome was adapted for sexing mouse early embryos using the polymerase chain reaction (PCR) method. Sry and Zfy genes located in the sex-determining region of the Y chromosome were chosen for Y-specific target sequences, and DXNds3 sequence on the X chromosome was chosen for control. The two-step PCR method using two pairs of primers for each of the target sequences was employed for detecting the sequences. When DNAs of male and female mice were amplified with these primers, male-specific fragments were detected even in DNAs that were equivalent in amount to two cells. Mouse embryos at the two-cell stage were separated into two individual blastomeres, and one blastomere was karyotyped at the second cleavage. The remaining blastomere was subjected to PCR amplification immediately or after having been cultured for 48 h up to the morula stage. The Sry and Zfy sequences were detected in about half the embryos; detection of the Sry and Zfy sequences corresponded exactly to the presence of the Y chromosome, except in one sample of male morula in which embryos may have been lost before the PCR amplification. It is concluded that the sex of mouse preimplantation embryos can be accurately determined through detection of the Y-specific sequences using the two-step PCR method, even with the single blastomeres separated at the two-cell stage.     

未经休眠处理的体细胞用于异种核移植

自“多莉”诞生以来,在全世界掀起了一场体细胞克隆的浪潮,许多体细胞克隆动物,如小鼠、山羊、牛、猪等纷纷问世。围绕体细胞克隆的供体细胞周期问题,学术界存在两种不同的观点,一是Wilmut等认为体细胞必须经过休眠处理,使细胞停滞在G0/G1期,或者采用以G0/G1期为主的活体细胞作为供体,这是克隆成功的关键,这一方面的报道已有很多。第二是Cibelli等认为不必对细胞作     

Swine in Biomedical Research: Creating the Building Blocks of Animal Models

Abstract

Sex of preimplantation porcine embryos was determined by DNA amplification using porcine male(Y chromosome)‐specific DNA primers in the polymerase chain reaction (PCR). In order to determine the sensitivity of this sexing method, single porcine embryos ranging from unfertilized ova to the blastocyst stage were amplified in the PCR using the Y‐specific primers, and analyzed by ethidium bromide‐staining of polyacrylamide gels. The 192 bp product which denotes the presence of the Y chromosome was seen in the embryos. The unfertilized ova which is of female origin gave no product. These results are representative of PCR analysis of a total of 34 swine embryos.

Results obtained using the PCR for sexing were validated by karyotyping and confirmed by in situ hybridization with the porcine Y‐chromosome‐specific probe. In order to confirm the sex of the embryos determined by PCR, 10 day‐old porcine preimplantation embryos were biopsied to produce a small number of cells for sex determination via PCR, while the remainder of the embryo was prepared for in situ hybridization using the biotinylated probe. In situ hybridization performed on embryos shown to be male by PCR, showed pinpoint fluorescence within the nuclei, similar to that obtained when male porcine lymphocytes were hybridized. No evidence of fluorescence was seen when in situ hybridization was performed in parallel on embryos determined to be female by the PCR.

The PCR was found to be a relatively fast, accurate and reproducible means of sex determination of swine preimplantation embryos. This capability could have significant impact on animal breeding and production programs by using PCR as a screening tool for traits of economic importance.     

A Simple Method for Transportation of Mouse Embryos Using Microtubes and a Warm Box

Generally, transportation of preimplantation embryos without freezing requires incubators that can maintain an optimal culture environment with a suitable gas phase, temperature, and humidity. Such incubators are expensive to transport. We reported previously that normal offspring were obtained when the gas phase and temperature could be maintained during transportation. However, that system used plastic dishes for embryo culture and is unsuitable for long-distance transport of live embryos. Here, we developed a simple low-cost embryo transportation system. Instead of plastic dishes, several types of microtubes—usually used for molecular analysis—were tested for embryo culture. When they were washed and attached to a gas-permeable film, the rate of embryo development from the 1-cell to blastocyst stage was more than 90%. The quality of these blastocysts and the rate of full-term development after embryo transfer to recipient female mice were similar to those of a dish-cultured control group. Next, we developed a small warm box powered by a battery instead of mains power, which could maintain an optimal temperature for embryo development during transport. When 1-cell embryos derived from BDF1, C57BL/6, C3H/He and ICR mouse strains were transported by a parcel-delivery service over 3 days using microtubes and the box, they developed to blastocysts with rates similar to controls. After the embryos had been transferred into recipient female mice, healthy offspring were obtained without any losses except for the C3H/He strain. Thus, transport of mouse embryos is possible using this very simple method, which might prove useful in the field of reproductive medicine.     

Comparison of gene expression in male and female mouse blastocysts revealed imprinting of the X-linked gene, Rhox5/Pem, at preimplantation stages

Mammalian male preimplantation embryos develop more quickly than females . Using enhanced green fluorescent protein (EGFP)-tagged X chromosomes to identify the sex of the embryos, we compared gene expression patterns between male and female mouse blastocysts by DNA microarray. We detected nearly 600 genes with statistically significant sex-linked expression; most differed by 2-fold or less. Of 11 genes showing greater than 2.5-fold differences, four were expressed exclusively or nearly exclusively sex dependently. Two genes (Dby and Eif2s3y) were mapped to the Y chromosome and were expressed in male blastocysts. The remaining two (Rhox5/Pem and Xist) were mapped to the X chromosome and were predominantly expressed in female blastocysts. Moreover, Rhox5/Pem was expressed predominantly from the paternally inherited X chromosome, indicating sex differences in early epigenetic gene regulation.     

H-Y antigen: No evidence for alleles in wild strains of mice

H-Y antigen(s) coded or controlled by the Y chromosome in a variety of wild mouse strains have been compared with those of the inbred laboratory strains C57BL/6 (B6) and C57BL/10 (B10). H-Y antigen(s) were detected by H-2-restricted cytotoxic T cells from B6 and B10 female mice primed in vivo and boosted in vitro with syngeneic male spleen cells: There was no difference in the degree of H-Y specific lysis of male cells from the C57BL strains and of F₁ hybrids or B6 congenic mice carrying the Y chromosome from the wild mouse strains examined. This result indicated that at the level of target cell specificity the H-Y antigen(s) from wild and laboratory strains were indistinguishable. H-Y antigen(s) were also found to be indistinguishable at the level of the in vitro induction of the anti H-Y cytotoxic response: F₁ female mice, primed in vivo and boosted in vitro with homologous F₁ male cells, all made H-Y-specific responses and where it could be examined, the target cell specificity of the anti-H-Y cytotoxic cells showed that B10 male cells as well as the homologous F₁ male cells (where the Y chromosome was derived from the wild strain) were good targets. Finally, possible differences in H-Y transplantation antigens between the wild strains and the B10 laboratory strain were examined by grafting F₁ male mice, the progeny of B10 females, and wild strain males with B10 male skin. These grafts were not rejected during an observation period of more than 9 months. Taken together, neither the cytotoxic data nor the skin graft data provide any evidence for allelism of H-Y even though the mouse strains examined were collected from widely disparate geographical locations.