应用cDNA芯片分析79个新基因的人胚组织表达谱

大规模cDNA测序和生物信息学技术相结合,得到来自于商品化的人胚肾cDNA文库79个代表新基因的表达序列标签(EST).随后,采用高速度机械手制备这些cDNA的基因芯片,用于鉴定79个新基因的ESTs在20周、26周两个胚胎时期6种组织中的基因表达状况,以研究这些EST片段代表的新基因功能提供线索.通过芯片杂交及结果分析,得到同一个组织两个不同时相8个差异表达的基因,随后的RNA印迹分析的结果与芯片杂交的结果相一致.     

多发性骨髓瘤细胞中一个新的Alu超基因家族成员的克隆与分析

根据Genebank收录的多发性骨髓瘤细胞株（ARH－77）表达上调EST AF497797设计引物,采用半定量RT－PCR证实了多发性骨髓瘤患者及正常人骨髓细胞中该expressed sequence tages(EST)存在表达差异。用EST AF497797作探针筛选人胚肾cDNA文库,获得cDNA克隆经测序并用生物信息学方法对该序列进行了初步分析。AF497797在多发性骨髓瘤患者骨髓中确有较高的表达,而在正常人骨髓细胞中低表达。获得的全长cDNA克隆序列长1248bp(Genebank登录号：AY094612）。生物信息学分析显示该片段全长cDNA编码44个氨基酸的蛋白产物且可能属于Alu家族成员。基因AY094612为一个在多发性骨髓瘤中表达上调的新基因,其改变可能与多发性骨髓瘤的发生与发展有关。     

小鼠睾丸生精细胞凋亡相关基因SRG2的分子克隆

从已获得的在隐睾和正常睾丸对照中表达量有明显差异的EST片段 (BE6 4 4 5 4 2 )入手 ,利用网上生物信息学克隆了该基因全长 ,GenBank登录号为AF395 0 83。从小鼠睾丸cDNA文库中分离出该基因完整阅读框cDNA ,SRG2基因的cDNA全长为 10 5 8bp ,编码由 2 95个氨基酸组成、分子量为 335 79、等电点为 9.6 4的蛋白质 ,与人类同源基因TSARG2相似性为 78% ,与已知蛋白质无明显同源性。RT PCR结果表明该基因只在睾丸中有高表达。     

用一个简单快速的RT-PCR技术筛选白细胞介素-6作用相关基因

为了研究白细胞介素-6(IL-6)作用相关基因以及一些可能受IL-6调控的基因,利用一个简单快速的以PCR为基础的方案,检测了IL-6处理和未处理的Sko007细胞中基因表达的差异,克隆并鉴定了差异表达基因的cDNA片段.首先用6-mer寡核苷酸引物进行反转录从而最大限度地将mRNA编码区序列生成cDNA;然后用2或3个较长的随机引物进行PCR扩增,并以不同引物组合重复PCR增扩;扩增产物在2%琼脂糖凝胶上电泳分离,回收差异片段并直接用于克隆、测序及进一步分析.在此研究中,获得了3个表达序列标签(EST),其中一个为新的基因片段,反向RNA杂交有力证实了它们与IL-6作用的相关性.进一步的生物信息学分析表明,新基因片段STRF17在多种组织中表达.     

鼻咽癌上皮细胞株HNE1差异表达基因的分离与鉴定

为了分离鼻咽癌差异表达基因 ,应用抑制性扣除杂交技术 ,在正向抑制性扣除杂交中 ,以鼻咽癌上皮细胞株HNE1cDNA作为检测子 ,以人胚鼻咽上皮细胞cDNA作为驱赶子 ;在反向抑制性扣除杂交中 ,以人胚鼻咽上皮细胞cDNA作为检测子 ,以鼻咽癌上皮细胞株HNE1cDNA作为驱赶子 ,分别通过抑制性扣除杂交 ,构建了鼻咽癌上皮细胞株HNE1表达下调和表达上调的两个扣除cDNA文库 .从鼻咽癌相关的扣除cDNA文库中随机挑取 1 2 0 0个克隆 ,采用菌落PCR扩增其插入cDNA片段 ,自动点膜制备成cDNA微阵列膜 ,分别用鼻咽癌上皮细胞株HNE1、人胚鼻咽上皮mRNA经逆转录标记cDNA探针 ,分别与cDNA微阵列膜杂交 ,通过杂交信号的自动扫描分析 ,对杂交信号存在 5倍差异的克隆进行测序 ,获得了 1 0个鼻咽癌差异表达基因的cDNA片段 ,其中 3个为新基因序列 ,其GenBank登录号为 :AF5 1 0 1 88、AF5 1 0 1 89和AF5 1 0 1 90 ,7个代表已知基因序列 .采用RT PCR证实S1 0 0A8,CK1 9和RBP1基因在人胚鼻咽上皮中高表达而在鼻咽癌细胞株HNE1中低表达 .这些结果显示上述基因可能是鼻咽癌发生的重要因素     

一个鼻咽癌相关EST的鉴定及其全长cDNA序列分析

鼻咽癌是我国南方及东南亚地区常见的恶性肿瘤之一.通过对鼻咽癌染色体高频率杂合性丢失区域3p21的表达序列标签(expressedsequencetag,EST)进行同源性比较分析,运用逆转录聚合酶链式反应的方法,筛选到一个在41.18%(14/34)的鼻咽癌活检组织及20.0%(1/5)的鼻咽癌细胞系中表达下调的ESTBG772301;并用Northern杂交方法,检测了该EST在多种正常成人组织中的表达状况及其所代表基因的转录本大小.在此基础上,对该EST来源的cDNA克隆(IMAGE:4839190)进行直接测序,获得了一个全长为2377bp的新cDNA序列;经生物信息学分析,发现它与已知基因序列无明显同源性,属于一个新基因,定位于染色体3p21.3,被命名为鼻咽癌表达下调基因(NPCEDRG,GenBank登录号:AF538150).其编码的蛋白质含169个氨基酸,与一个已报道的在进化上相对保守、功能未知的人类蛋白Nicolin1(简称NICN1)N端170个氨基酸残基的序列同源性为97%,但缺少NICN1蛋白C端43个氨基酸残基,可能是nicolin1基因不同剪接本的编码产物.     

染色体7q32-ter鼻咽癌相关基因的初步研究

为克隆7q32-ter区域等位基因杂合性丢失最小共同缺失区的鼻咽癌相关基因.以STS D7S509为探针,PCR法筛选位于该区的细菌人工染色体(BAC)克隆,应用EST介导的定位-候选克隆策略并结合生物信息学筛选出在鼻咽癌细胞株和活检组织中表达增强的EST AA773454,cDNA克隆测序和生物信息学资源获取全长cDNA,DNA印迹和甲基化分析研究其表达增强的机制.结果表明,克隆的NAG18基因cDNA全长802 bp,编码227个氨基酸,定位于胞核.该基因分别与人、鼠TAXREB107基因及RPL6基因高度同源.其表达增强的机制不是基因拷贝数的丢失和甲基化位点的改变.可以断定NAG18是定位于7q32-ter最小共同缺失区的鼻咽癌相关基因,它是一高度保守的基因,参与了DNA的转录活化.     

多发性骨髓瘤细胞中一个表达上调基因的克隆与分析

根据GenBank收录的多发性骨髓瘤细胞株 (ARH 77)表达上调ESTAF4 2 5 30 0设计引物 ,运用RT PCR检测了 5例多发性骨髓瘤患者及 4例正常人骨髓细胞中该EST的表达水平 .Northern印迹杂交分析该EST在多种组织中的表达 .进一步利用该EST作探针 ,筛选ARH 77cDNA文库 ,获得全长cDNA克隆 ,对该序列进行了分析 .结果显示 ,该EST在多发性骨髓瘤患者骨髓细胞中亦有较高的表达 ,而在正常人骨髓细胞中低表达 .经测序证实 ,该cDNA全长为 4 5 2bp(GenBank收录号 :AF4 87338) .预测其编码一个 5 7个氨基酸的小分子量蛋白质 ,属于与DNA复制有关的解旋酶 引物酶基因家族的新成员 .该基因在多发性骨髓瘤细胞中表达上调 ,其表达水平的改变可能与多发性骨髓瘤的发生与发展有关     

EST分析技术在鸡基因组学研究中的应用

表达序列标签（EST）是由大量随机取出的cDNA库克隆经测序得到的组织或细胞基因组的一段cDNA序列,一个EST代表生物体某种组织某一时期的一个表达基因。综述了EST分析技术在鸡基因组研究中的应用。如用于鉴定、发现和预测鸡的新基因,用于基因图谱的绘制,用于筛选基因的单核苷酸多态性（SNP）位点,用于基因表达分析和基因芯片制作等。EST数据库和生物信息学的联合分析技术在推动家鸡后基因组的研究中发挥着重要的作用。     

定位于染色体9p21-22的一个新基因UBAP1的克隆测序及在鼻咽癌中的表达分析

 在染色体 9p2 1 2 2鼻咽癌杂合性丢失 (lossofheterozygosity,LOH)高频区 ,应用EST介导的定位 侯选克隆策略 ,用RT PCR及Northern杂交检测了 2 2个表达序列标记 (expressedsequencetag ,EST)在鼻咽癌细胞株HNE1和原代培养的正常鼻咽上皮细胞中的表达差异 ,并对其中一个在鼻咽癌细胞株HNE1中表达下调的EST检测了在鼻咽癌活检组织中的表达 .用生物信息学方法获得其全长cDNA序列 ,GenBank登录号AF2 2 2 0 4 3.该基因cDNA全长 2 70 1bp ,其开放阅读框 (openreadingframe ,ORF)编码一个含 50 2个氨基酸、分子量为 55kD的碱性蛋白质 ,在蛋白羧基端含有 2个连续的重要UBA功能域 (ubiquitinassociateddomain) ,属于遍在蛋白相关蛋白家族的一个新成员 ,经国际人类基因命名委员会同意 ,将其命名为UBAP1 (ubiquitinassociatedprotein 1 ) .Northern表达分析显示UBAP1在所检测的人组织中广泛表达 ,但在人的心脏、骨骼肌及肝脏中的表达较强 .UBAP1基因在63 2 % ( 1 2 1 9)的鼻咽癌活检组织中表达下调 .UBAP1基因作为一个遍在蛋白相关蛋白家族的新成员 ,结合其在 9p的重要定位信息 ,有必要进一步研究其表达下调参与鼻咽癌发生发展的可能机制 .     

cDNA cloning and function analysis of two novel erythroid differentiation related genes

Our previous studies showed that some nuclear proteins that were expressed especially during terminal differentiation of erythroid cells might interact directly or indirectly with HS2 sequence to form the HS2-protein complexes and thus play an important role in the globin gene regulation and erythroid differentiation. Monoclonal antibodies against the nuclear proteins of terminal differentiated erythroid cells, including intermediate and late erythroblasts of human fetal liver and hemin induced K562 cells, were prepared by hybridoma technique. The monoclonal antibodies were used to screen λ-gtll human cDNA expression library of fetal liver in order to obtain the relevant cDNA clones. By the analysis of their cDNA clones and the identification of the proteins' functions, the regulation mechanism of the HS2 binding proteins might be better understood. Two cDNA clones (GenBank accession number AF040247 and AF040248 respectively) were obtained and one of them owns a full length and the other encodes a prote     

cDNA cloning and function analysis of two novel erythroid differentiation related genes

Our previous studies showed that some nuclear proteins that wereexpressed especially during terminal differentiation of erythroid cells might interact directly or indirectly with HS2 sequence to form the HS2-protein complexes and thus play an important role in the globin gene regulation and erythroid differentiation. Monoclonal antibodies against the nuclear proteins of terminal differentiated erythroid cells, including intermediate and late erythroblasts of human fetal liver and hemin induced K562 cells, were prepared by hybridoma technique. The monoclonal antibodies were used to screen l-gtll human cDNA expression library of fetal liver in order to obtain the rele-vant cDNA clones. By the analysis of their cDNA clones and the identification of the proteins' func-tions, the regulation mechanism of the HS2 binding proteins might be better understood. Two cDNA clones (GenBank accession number AF040247 and AF040248 respectively) were obtained and one of them owns a full length and the other encodes a protein characterized by a leucine-zipper domain. Both of them were expressed differentially in K562 cells and hemin-induced K562 cells. The evidence suggested that both of them were involved in erythroid differentiation. We investigat-ed the expression pattern of EDRF1 and EDRF2 by RT-PCR technique. The results of RT-PCR suggested that EDRF1 and EDRF2 might play a critical role in early stage of organ development and histological differentiation. EDRF1 and EDRF2 might start the program of erythroid develop-ment, and also regulate the development of erythroid tissue and the expression of globin gene at different stage of the development.     

与抑制K562细胞向红系分化相关的Attractin基因的分离和初步鉴定

应用差异显示PCR（DDRT-PCR）方法分离野生型K562细胞株和能表达人β－珠蛋白基因的变种K562细胞株的4个差异cDNA片段,序列测定后,挑选差异最明显的片段dd1,经过RT-PCR、Northern 印迹鉴定确实为两株细胞间的差异片段,测序后经同源性分析等,发现其所对应的基因是吸引素（Attractin,GenBank注册号AF106861）。 根据其结构预测,Attractin有可能是K562 细胞表面一个黏附因子受体,与抑制K562细胞向红系分化有关。 Abstract:Differential display PCR method was used to isolate four differential display fragments between the wild type K562 cell line and the variant type K562 cell line that expressed the human β-globin gene.After sequencing,the most remarkable different fragment,named dd1,was selected for further study.The analysis of RT-PCR and Northern blot hybridization showed that dd1 was exactly the differentiation fragment between the two cell lines.The homology analysis indicated that dd1 was matched to Attractin (GeneBank registration No.AF106861).It might be an adhesion receptor related to inhibiting erythroid differentiation based on its structure.     

Initial function analysis of a novel erythroid differentiation related gene EDRF1

Erythroid differentiation depends on the establishment of specific patterns of gene expression. Hypersensitive site 2 (HS2, serving as a major enhancer of globin genes)-binding proteins may be involved in its natural open chromosomal environment formation. Previously we prepared monoclonal antibodies against HS2-binding nuclear proteins of terminal differentiated erythroid cells. By utilizing the monoclonal antibodies, we screened λ-gt11 human fetal liver cDNA expression library and obtained one cDNA clone, which was named erythroid differentiation related gene (EDRF1, Genbank accession number AF040247), encompassing an entire open reading frame. We investigated the expression pattern ofEDRF1 by RT-PCR technique. And a clue to the function ofEDRF1 has been found from confirmation of high levels ofEDRF1 mRNA in differentiated K562 and human fetal liver tissue. To illuminate the function ofEDRF1 in K562 cells, sense and antisenseEDRF1 constructs were prepared and transfected into K562 cells. α-globin mRNA was down-regulated and EpoR (erythropoietin receptor) mRNA expression was increased in antisense transfected cells. Cells transfected with sense construct grew more slowly than control cells suggested by [³H] thimidine incorporation experiments. Suppression of K562 proliferation was accompanied by increased spontaneous hemoglobin synthesis demonstrated by spectrometry. K562 cells transfected with sense construct exhibited reduced clongenicity compared with control cells in methycellulose culture. These data provided the evidence thatEDRF1 can influence globin expression and hemoglobin synthesis in K562 cells and modulated self-renewal in K562 cells.     

Initial function analysis of a novel erythroid differentiation related geneEDRF1

Erythroid differentiation depends on the establishment of specific patterns of gene expression. Hypersensitive site 2 (HS2, serving as a major enhancer of globin genes)-binding proteins may be involved in its natural open chromosomal environment formation. Previously we prepared monoclonal antibodies against HS2-binding nuclear proteins of terminal differentiated erythroid cells. By utilizing the monoclonal antibodies, we screened λ-gt11 human fetal liver cDNA expression library and obtained one cDNA clone, which was named erythroid differentiation related gene (EDRF1, Genbank accession number AF040247), encompassing an entire open reading frame. We investigated the expression pattern ofEDRF1 by RT-PCR technique. And a clue to the function ofEDRF1 has been found from confirmation of high levels ofEDRF1 mRNA in differentiated K562 and human fetal liver tissue. To illuminate the function ofEDRF1 in K562 cells, sense and antisenseEDRF1 constructs were prepared and transfected into K562 cells. α-globin mRNA was down-regulated and EpoR (erythropoietin receptor) mRNA expression was increased in antisense transfected cells. Cells transfected with sense construct grew more slowly than control cells suggested by [³H] thimidine incorporation experiments. Suppression of K562 proliferation was accompanied by increased spontaneous hemoglobin synthesis demonstrated by spectrometry. K562 cells transfected with sense construct exhibited reduced clongenicity compared with control cells in methycellulose culture. These data provided the evidence thatEDRF1 can influence globin expression and hemoglobin synthesis in K562 cells and modulated self-renewal in K562 cells.     

ERK signaling pathway is differentially involved in erythroid differentiation of K562 cells depending on time and the inducing agent

K562 cells can be induced to differentiate along the erythroid lineage by a variety of chemical compounds, including hemin, butyrate, cisplatin and ara-C. Differential signaling through MAP kinases has been suggested to be involved in this differentiation process. We have investigated the involvement of ERK activation/inhibition in hemin-, butyrate-, cisplatin- and ara-C-induced erythroid differentiation using the K562 cell line. ERK activity decreased for 2-4h after administration of either inducing agent. ERK was then activated by hemin and cisplatin, while ERK phosphorylation remained decreased during incubation with butyrate and ara-C. There was no activation of JNK or p38. The MEK-1 inhibitors UO126 or PD98059 induced erythroid differentiation in K562 cells and acted additively with butyrate. Inhibition of MEK-1 reduced the hemoglobin accumulation by hemin and cisplatin; erythroid differentiation by ara-C was unchanged. The results suggest that inhibition of signaling through ERK in K562 cells may be needed to enter the erythroid differentiation process, while after initiation both activation and inhibition of signaling through ERK enhance erythroid differentiation, which, however, is dependent on the inducing compound.