维甲酸对鼻咽癌细胞生长、表型和瘤基因表达的作用

研究了维甲酸（ＲＡ）对鼻咽癌细胞生长、表型和癌基因表达的作用．用ＲＡ诱导鼻咽癌细胞,绘制诱导前后的细胞曲线,观察细胞形态,并用Ｎｏｒｔｈｅｒｎ杂交和ＤＮａｓｅⅠ超敏感区分析法检测基因表达和调控．结果表明,ＲＡ能显著抑制鼻咽癌细胞的生长,前５ｄ下降约５０％．ＲＡ处理后的细胞从典型的多边形形态变成扁平、细长,类似纤维细胞状的形态．ＲＡ诱导前ｃ－ｍｙｃ基因和ｃ－Ｈａ－ｒａｓ基因ＨＮＥ２细胞中高表达,而诱导后ｃ－ｍｙｃ基因表达水平急剧下降,ｃ－Ｈａ－ｒａｓ基因无明显改变．在实验中还发现ＲＡ诱导前后的ｃ－ｍｙｃ基因和ｃ－Ｈａ－ｒａｓ基因中一些重要的超敏感位点和它们的功能．由实验结果可得到如下结论：ＲＡ能促进鼻咽癌细胞分化,通过对染色体上调控位点的作用来抑制ｃ－ｍｙｃ基因的表达,ＤＮａｓｅⅠ超敏感位点与细胞的分化程度、细胞的组织特异性和基因表达状态有关,ｃ－ｍｙｃ基因可通过不同的调控方式而失活．     

外源性神经节苷脂GM3影响人肝癌细胞生长的可能机制的初步研究

通过苔酚蓝染色细胞发现,外源性ＧＭ３能明显抑制人肝癌细胞株ＳＭＭＣ－７７２１细胞生长,在ＧＭ３处理３ｄ时,出现明显差异,通过ＮｏｒｔｈｅｒｎＢｌｏｔ分析发现,外源性ＧＭ３可明显影响人肝癌细胞株ＳＭＭＣ－７７２１细胞中ｃ－ｆｏｓ、ｃ－ｊｕｎ、ｃ－ｍｙｃ和Ｎ－ｒａｓ四种癌基因的ｍＲＮＡ表达,未经ＧＭ３处理的细胞中没有检测到ｃ－ｆｏｓｍＲＮＡ,但ｃ－ｊｕｎ微量表达,并有ｃ－ｍｙｃ和Ｎ－ｒａｓｍＲＮＡ的高     

r射线诱发大鼠胚胎细胞转化与N—ras的激活

以ｒ射线诱发转化的大鼠胚胎细胞（ＲＥＣ：ｃｙｃ：ｒ３３）的ＤＮＡ构建粘粒基因库,用总基因库ＤＮＡ转染ＮＩＨ／３Ｔ３细胞,产生转化灶的ＤＮＡ作二轮转染,二轮转化的ＮＩＨ３／Ｔ３细胞内有大鼠ＲＥＣ：ｍｙｃ：ｒ３３ＤＮＡ中具转化活性的Ｎ－ｒａｓ基因,用不对称ＰＣＲ和ＤＮＡ序列分析法证明,ＲＥＣ：ｍｙｃ：ｒ３３细胞中鼠Ｎ－ｒａｓ的活化是由于第６１位密码子的Ａ→Ｇ点空为。ＮＩＨ／３Ｔ３转化灶中鼠Ｎ－ｒａｓ也     

应用荧光原位杂交和RFLP标记检测多小穗小麦新种质10—A中的黑麦染 …

利用ＡＰＡＧＥ,荧光原位杂交技术和ＲＦＬＰ标记,对导入黑麦（ＳｅｃａｌｅｃｅｒｅａｌｅＬ．）多小穗等性状创制的小麦新种质１０－Ａ进行了分子标记检测,ＡＰＡＧＥ分析发现,１０－Ａ与其他１ＲＳ／１ＢＬ易位系一样,含有１ＲＳ的醇溶蛋白标记位点Ｇｌｄ１Ｂ３。以黑麦基因组总ＤＮＡ作探针,用中国春（Ｔｒｉｔｉｃｕｍａｅｓｔｉｕｍｃｖ．ＣｈｉｎｅｓｅＳｐｒｉｎｇ）基因组ＤＮＡ作封阻,与１０－Ａ根尖细胞有丝分裂染     

HSP_(70)基因表达对高粱育性的影响(英文)

高粱细胞质雄性不育系３１９７Ａ（３Ａ）在常温条件下是不育的（Ｆｉｇｓ．１１＆２）,经热激（４５℃）诱导不同程度地恢复了育性（Ｆｉｇｓ．１３＆４）,为研究其不育机理提供了线索。热激２ｈ后,３Ａ中即可产生一类线粒体热激蛋白（ＨＳＰｓ）。其中,分子量为７０ｋＤ的ＨＳＰ７０含量最高,也最为稳定。不过,３Ａ中ＨＳＰｓ的稳定性弱于保持系３１９７Ｂ（３Ｂ）（Ｆｉｇ．２,Ｐａｎｅｌｓ１～４）。放线菌素Ｄ抑制ＨＳＰｓ的合成,而氯霉素无此作用（Ｆｉｇ．２,Ｐａｎｅｌｓ５＆６）,表明：ＨＳＰｓ是由核基因编码、在细胞质中合成、再跨膜转运到线粒体中的。３Ａ幼穗经热激后,线粒体的总蛋白量猛增了２．７倍（Ｆｉｇ．３）,达到３Ｂ的水平,育性亦变为可育的。Ｆｉｇ．４表明：ＨＳＰ７０反义链ｃＤＮＡ（Ｒ１）能进入到３Ｂ花药细胞中,并与靶ＲＮＡ（ＨＳＣ７０ｍＲＮＡ）结合,而对照、正义链ｃＤＮＡ（Ｄ）链无此反应。由此、再增加一个通用保守序列的反义链ｃＤＮＡ（Ｒ２）、共两个探针（Ｒ１、Ｒ２）,可以检测到：３Ａ在常温下没有能力合成ＨＳＣ７０ｍＲＮＡ（Ｆｉｇ．５）,而在热激条件下,转变为有能力（Ｆｉｇ．６）。启示：３Ａ在热激条件下由不育转变为可育     

LA－90细胞在温度转化过程中蛋白质酪氨酸磷酸化作用研究

ＬＡ－９０细胞在温度转化过程中蛋白质酪氨酸磷酸化作用研究夏英,高漫,颜卉君,吴国利（北京师范大学生物系生物化学及分子生物学研究室,１００８７５）关键词酪氨酸蛋白激酶;磷酸酪氨酸蛋白磷酸酶;细胞转化ｉｓ－ＲＳＶＬＡ－９０细胞是ＲＳＶ转染的小鼠３Ｔ３细胞...     

c-fos基因在内皮素-1促肺泡Ⅱ型细胞表面活性物质合成中的作用

应用反义技术探讨ｃ－ｆｏｓ基因ＥＴ－１调控肺泡Ⅱ型细胞（ＡＴⅡ）表面活性物质（ＰＳ）合成的胞内信号转导中的作用,结果显示：（１）内皮素－１（ＥＴ－１）可提高ＡＴⅡ细胞的＾３Ｈ－胆碱掺入。（２）蛋白激酶Ｃ（ＰＫＣ）激活剂ＰＭＡ可使ＡＴⅡ细胞的＾３Ｈ－胆碱掺入量增加,ＰＫＣ抑制剂Ｈ７可抑制ＥＴ－１的促ＰＳ合成效应。（３）ＥＴ－１和ＰＭＡ可显著提高Ｆｏｓ蛋白表达量,Ｈ７和ｃ－ｆｏｓ反义寡核苷酸（ＯＤＮ）     

大肠杆菌精氨酰－tRNA合成酶的Lys306为酶活力所必需

将大肠杆菌精氨酰ｔＲＮＡ合成酶（ＡｒｇＲＳ）上Ｌｙｓ３０６用基因点突变的方法分别变为Ａｌａ和Ａｒｇ的密码子;得到变种基因ａｒｇｓ３０６ＫＡ和ａｒｇｓ３０６ＫＲ。变种基因重组在ｐＵＣ１８上,转化到大肠杆菌ＴＧ１中,转化子中ＡｒｇＲＳ及其变种ＡｒｇＲＳ３０６ＫＡ和ＡｒｇＲＳ３０６ＫＲ所表达的蛋白量至少为ＴＧ１表达ＡｒｇＲＳ蛋白量的１００倍。细胞粗抽提液中ＡｒｇＲＳ的比活ＴＧ１、转化子ｐＵＣ１８－ａｒｇｓ、ｐＵＣ１８－ａｒｇｓ３０６ＫＡ和ｐＵＣ１８－ａｒｇｓ３０６ＫＲ分别为１．６５、２１０、１．８和３８单位／毫克。结果表明ＡｒｓＲＳ的Ｌｙｓ３０６为Ａｌａ取代使活力完全丧失;若被Ａｒｇ取代,则活力丧失８０％以上。Ｌｙｓ３０６为ＡｒｇＲＳ活力所必需。     

抑制肺癌及乳癌的基因

许多基因编码抑制细胞生长的蛋白质 ,这些基因中的某些基因抑制肿瘤生长 .以前发现ＢＲＣＡ1基因抑制乳癌生长 ,现发现基因ＲＡＳＳＦ1Ａ也是这种基因 .在 2 0 0 1年 5月 2日的ＪｏｕｒｎａｌｏｆｔｈｅＮａｔｉｏｎａｌＣａｎｃｅｒＩｎｓｔｉｔｕｔｅ上报道的一项研究确认 ,许多肺癌与乳癌缺乏有功能的ＲＡＳＳＦ1Ａ .研究者发现 ,将恢复ＲＡＳＳＦ1Ａ功能的人癌细胞移植到小鼠体内 ,可防止小鼠发生肿瘤 .研究者用外科手术从肺癌和乳癌病人身上取得癌细胞来创建可在实验室生长的细胞系 .从小细胞肺癌病人取得的 32个细胞系中的ＲＡＳＳＦ1…     

大肠杆菌精氨酰—tRNA合成酶的Lys306为酶活力所必需

将大肠杆菌精氨酰ｔＲＮＡ合成酶（ＡｒｇＲＳ）上Ｌｙｓ３０６用基因点突变的方法分别变为Ａｌａ和Ａｒｇ的密码子,得到变种基因ａｒｇｓ３０６ＫＡ和ａｒｇｓ３０６ＫＲ。变种基因重组在ｐＵＣ１８上,转化到大肠杆菌ＴＧ１中,转化子中ＡｒｇＲＳ及其变种ＡｒｇＲＳ３０６ＫＡ和ＡｒｇＲＳ３０６ＫＲ所表达的蛋白量生活为ＴＧ１表达ＡｒｇＲＳ蛋白量的１００倍。细胞粗抽提液中ＡｒｇＲＳ的比活ＴＧ１,转化子ｐＵＣ１８－ａｒｇ     

Identification of guanine nucleotides bound to ras-encoded proteins in growing yeast cells

We have analyzed the guanine nucleotides bound to mammalian ras and yeast RAS proteins overexpressed in [32P]orthophosphate-labeled cultures of exponentially growing Saccharomyces cerevisiae cells. Whereas S. cerevisiae RAS1 and RAS2 proteins were immunoprecipitated bound entirely to GDP, mammalian Harvey ras was isolated with GTP and GDP bound in near-equimolar proportions. In a strain overexpressing a RAS2 variant where the RAS unique C-terminal domain was deleted, both GTP and GDP were detected in a ratio of 3:97. Increased amounts of GTP (16-75% of total guanine nucleotide) were observed bound to all ras proteins containing mutations that inhibit GTP hydrolytic activity. Increasing proportions of GTP bound to the various ras proteins correlated with increasing biological potency to bypass cdc25 lethality in yeast.     

Isolation and Characterization of Temperature-Sensitive Mutations in the Ras2 and Cyr1 Genes of Saccharomyces Cerevisiae

The yeast Saccharomyces cerevisiae contains two ras homologues, RAS1 and RAS2, whose products have been shown to modulate the activity of adenylate cyclase encoded by the CYR1 gene. To isolate temperature-sensitive mutations in the RAS2 gene, we constructed a plasmid carrying a RAS2 gene whose expression is under the control of the galactose-inducible GAL1 promoter. A ras1 strain transformed with this plasmid was subjected to ethyl methanesulfonate mutagenesis and nystatin enrichment. Screening of approximately 13,000 mutagenized colonies for galactose-dependent growth at a high temperature (37 degrees) yielded six temperature-sensitive ras2 (ras2ts) mutations and one temperature-sensitive cyr1 (cyr1ts) mutation that can be suppressed by overexpression or increased dosage of RAS2. Some ras2ts mutations were shown to be suppressed by an extra copy of CYR1. Therefore increased dosage of either RAS2 or CYR1 can suppress the temperature sensitivity caused by a mutation in the other. ras1 ras2ts and ras1 cyr1ts mutants arrested in the G1 phase of the cell cycle at the restrictive temperature, and showed pleiotropic phenotypes to varying degrees even at a temperature permissive for growth (25 degrees), including slow growth, sporulation on rich media, increased accumulation of glycogen, impaired growth on nonfermentable carbon sources, heat-shock resistance, impaired growth on low concentrations of glucose, and lithium sensitivity. Of these, impaired growth on low concentrations of glucose and sensitivity to lithium are new phenotypes, which have not been reported for mutants defective in the cAMP pathway.     

Adenylate cyclase activity of NIH 3T3 cells morphologically transformed by ras genes

The observed homology between G-proteins which regulate adenylate cyclase and ras proteins and the suggested role of ras in the regulation of adenylate cyclase in yeast prompted us to examine the regulation of adenylate cyclase in three cell lines: (i) NIH 3T3 cells, (ii) NIH 3T3 cells transformed by high levels of the normal rasH gene product and (iii) NIH 3T3 cells transformed by a mutated rasH gene product. We found that the regulation of adenylate cyclase by G-proteins is identical in the three cell lines, although the response of the transformed NIH 3T3 cells to agonists is strongly attenuated. Our data suggest that mammalian ras products do not interact directly with adenylate cyclase, although their increased expression may indirectly inhibit the interaction of adenylate cyclase stimulatory receptors with G-proteins.     

The overexpression of the 3' terminal region of the CDC25 gene of Saccharomyces cerevisiae causes growth inhibition and alteration of purine nucleotides pools.

The CDC25 gene is transcribed at a very low level in S. cerevisiae cells. We have studied the effects of an overexpression of this regulatory gene by cloning either the whole CDC25 open reading frame (pIND25-2 plasmid) or its 3' terminal portion (pIND25-1 plasmid) under the control of the inducible strong GAL promoter. The strain transformed with pIND25-2 produced high levels of CDC25 specific mRNA, induced by galactose. This strain does not show any apparent alteration of growth, both in glucose and in galactose. Instead the yeast cells transformed with pIND25-1, that overexpress the 3' terminal part of CDC25 gene, grow very slowly in galactose medium, while they grow normally in glucose medium. The nucleotides were extracted from transformed cells, separated by HPLC and quantitated. The ATP/ADP and GTP/GDP ratios were almost identical in control and in pIND25-2 transformed strains growing in glucose and in galactose, while the strain that overexpresses the 3' terminal portion of CDC25 gene showed a decrease of ATP/ADP ratio and a partial depletion of the GTP pool. The disruption of RAS genes was only partially able to 'cure' this phenotype. A ras2-ts1, ras1::URA3 strain, transformed with pIND25-1 plasmid, was able to grow in galactose at 36 degrees C. These results suggest that the carboxy-terminal domain of the CDC25 protein could stimulate an highly unregulated GTPase activity in yeast cells by interacting not only with RAS gene products but also with some other yeast G-proteins.     

Apoptosis and catastrophic cell death in benzo[a]pyrene-transformed human breast epithelial cells

Apoptosis and mitotic death, bi- and multinucleation, giant cells and micronucleation were investigated in human breast epithelial cell lines transformed by benzo[a]pyrene (BP) (BP1, BP1-E and BP1-E1 cells) and in BP1 cells transfected with the c-Ha-ras oncogene (BP1-Tras cells). Since BP induces apoptosis and the abnormal expression of ras genes elicits catastrophic mitosis, both cell death phenomena were expected to occur in this system, especially in BP1-Tras cells. Regardless of the cell line considered, single-nucleate cells were found to be eliminated preferentially through apoptosis, while bi- and multinucleate cells were eliminated through catastrophic mitosis. Apoptosis and catastrophic mitosis were observed in all cell lines but were significantly more frequent in BP1-Tras cells. The abnormal expression of Ha-ras in the latter cells may enhance in this system the effects of the BP apoptosis path reported for BP-transformed Hepa 1c1c7 hepatoma cells. Transfection with the ras oncogene also enhanced the mitotic disturbances, which produced multi- and micronucleation and mitotic death, possibly because of the genomic instability promoted by this oncogene in the BP-transformed cell line.     

Genetic analysis of yeast RAS1 and RAS2 genes

We present a genetic analysis of RAS1 and RAS2 of S. cerevisiae, two genes that are highly homologous to mammalian ras genes. By constructing in vitro ras genes disrupted by selectable genes and introducing these by gene replacement into the respective ras loci, we have determined that neither RAS1 nor RAS2 are by themselves essential genes. However, ras1 - ras2 - spores of doubly heterozygous diploids are incapable of resuming vegetative growth. We have determined that RAS1 is located on chromosome XV, 7 cM from ade2 and 63 cM from his3; and RAS2 is located on chromosome XIV, 2 cM from met4 . We have also constructed by site-directed mutagenesis a missense mutant, RAS2val19 , which encodes valine in place of glycine at the nineteenth amino acid position, the same sort of missense mutation that is found in some transforming alleles of mammalian ras genes. Diploid yeast cells that contain this mutation are incapable of sporulating efficiently, even when they contain wild-type alleles.     

Ras Signaling Is Required for Serum-Induced Hyphal Differentiation in Candida albicans

Serum induces Candida albicans to make a rapid morphological change from the yeast cell form to hyphae. Contrary to the previous reports, we found that serum albumin does not play a critical role in this morphological change. Instead, a filtrate (molecular mass, <1 kDa) devoid of serum albumin induces hyphae. To study genes controlling this response, we have isolated the RAS1 gene from C. albicans by complementation. The Candida Ras1 protein, like Ras1 and Ras2 of Saccharomyces cerevisiae, has a long C-terminal extension. Although RAS1 appears to be the only RAS gene present in the C. albicans genome, strains homozygous for a deletion of RAS1 (ras1-2/ras1-3) are viable. The Candida ras1-2/ras1-3 mutant fails to form germ tubes and hyphae in response to serum or to a serum filtrate but does form pseudohyphae. Moreover, strains expressing the dominant active RAS1(V13) allele manifest enhanced hyphal growth, whereas those expressing a dominant negative RAS1(A16) allele show reduced hyphal growth. These data show that low-molecular-weight molecules in serum induce hyphal differentiation in C. albicans through a Ras-mediated signal transduction pathway.     

Development of transformed phenotype induced by a human ras oncogene is inhibited by interferon

Mouse IFN inhibited the development of transformed foci in NIH 3T3 cultures transfected with the viral Ha-MuSV(ras) and Mo-MuSV(mos) oncogenes, or with the human bladder carcinoma ras EJ/T24 DNA. IFN treatment five or seven days after transfection was still effective in inhibiting the oncogenic transformation, but did not inhibit significantly the biochemical transformation induced by pSV2-neo or Ecogpt DNA, so that inhibition of ras-induced transformation was not a result of a general effect on the transfection process. Treatment with IFN did not alter the expression of ras EJ/T24 DNA after the transformed phenotype had been established.     

Role of a ras homolog in the life cycle of Schizosaccharomyces pombe

We have analyzed the function of the only ras homolog in S. pombe detectable by Southern blotting, ras1, which is homologous to mammalian ras genes and has been cloned. We have disrupted the ras1 gene and have replaced it with ras1Val17, which corresponds to a transforming variant of mammalian ras. Loss of ras1 activity by disruption results in the complete inability to mate. The cell body of a ras1- strain is extensively deformed, and a ras1-/ras1- diploid sporulates very poorly. Unlike RAS1 and RAS2 of S. cerevisiae, ras1 of S. pombe appears to have no effect on adenylate cyclase activity. This suggests that the target enzymes presumably modulated by ras proteins in signal transduction are not the same for all organisms.