Genomic Organization of the Human Skeletal Muscle Sodium Channel Gene

Voltage-dependent sodium channels are essential for normal membrane excitability and contractility in adult skeletal muscle. The gene encoding the principal sodium channel α-subunit isoform in human skeletal muscle (SCN4A) has recently been shown to harbor point mutations in certain hereditary forms of periodic paralysis. We have carried out an analysis of the detailed structure of this gene including delineation of intron-exon boundaries by genomic DNA cloning and sequence analysis. The complete coding region of SCN4A is found in 32.5 kb of genomic DNA and consists of 24 exons (54 to > 2.2 kb) and 23 introns (97 bp-4.85 kb). The exon organization of the gene shows no relationship to the predicted functional domains of the channel protein and splice junctions interrupt many of the transmembrane segments. The genomic organization of sodium channels may have been partially conserved during evolution as evidenced by the observation that 10 of the 24 splice junctions in SCN4A are positioned in homologous locations in a putative sodium channel gene in Drosophila (para). The information presented here should be extremely useful both for further identifying sodium channel mutations and for gaining a better understanding of sodium channel evolution.     

Genomic Organization of the Human SPOCK Gene and Its Chromosomal Localization to 5q31

SPOCK, previously identified as testican, is a modular proteoglycan that carries both chondroitin and heparan sulfate glycosaminoglycan side chains. The overall genomic organization has been established. The SPOCK gene spans at least 70 kb and is composed of 11 exons: the first half of the gene is dramatically expanded, but the second half is more compact.In situhybridization and YAC mapping independently linked the SPOCK gene to 5q31, a region containing an impressive number of genes encoding growth factors, cytokines, and neurotransmitter and hormone receptors. The gene is located between the IL9 and the EGR1 genes, bordering the smallest commonly deleted region of chromosome 5.     

人促红细胞生成素基因组基因和cDNA的克隆及其在COS－7细胞中的表达

利用ＰＣＲ技术,从正常人胎肝染色体ＤＮＡ中克隆到长度为１５７２ｂｐ的人促红细胞生成素（ＥＰＯ）基因组基因片段,它包含除第一个外显子和第一个内含子外所有外显子及内含子。再人工合成１３ｂｐ外显子１的编码区,并与１５７２ｂｐ片段拼接,从而得到除第一个内含子的人促红细胞生成素基因组基因。将克隆得到的ＥＰＯ基因插入载体ｐＳＶ２－ｄｈｆｒ得到ｐＳＶ２－ＥＰＯ表达载体,转染ＣＯＳ－７细胞后获得高效表达。利用自行研制的小鼠抗人ＥＰＯ单抗及兔抗人ＥＰＯ多抗,对表达产物进行ＥＬＩＳＡ定量测定,细胞分泌ＥＰＯ量高达２５１±７Ｕ／ｍｌ．Ｋｒｙｓｔａｌ法测得体外生物活性２４１．５±６．５Ｕ／ｍｌ．用ＥＰＯ单抗免疫沉淀结合ＳＤＳ－ＰＡＧＥ对转染细胞的表达产物做了进一步鉴定,清晰地看到了ＥＰＯ条带。从高效表达ＥＰＯ的转染细胞中分离纯化ｍＲＮＡ,用ＲＴ－ＰＣＲ方法扩增并克隆到ＥＰＯ的ｃＤＮＡ,这为ＥＰＯ在其它系统中的表达及ＥＰＯ的功能与结构的研究打下了基础。     

青蒿鲨烯合酶基因的克隆、结构分析与大肠杆菌表达

用RT-PCR方法从青蒿(Artemisia annua L.)中克隆了一个1539bp全长鲨烯合酶cDNA。青蒿鲨烯合酶氨基酸序列与拟南芥、烟草、人类、酵母鲨烯合酶的一致性分别为70％、77％、44％和39％。青蒿鲨烯合酶基因组DNA结构很复杂,包括14个外显子和13个内含子。全长的或C末端截短的鲨烯合酶cDNA被克隆进原核表达载体pET30a并在大肠杆菌(Escherichia coli)BL21(DE3)中诱导表达。但在含有全长的鲨烯合酶cDNA的大肠杆菌中并没有观察到预期大小的鲨烯合酶表达,而C末端截短疏水区30个氨基酸的鲨烯合酶可在大肠杆菌中过量表达。     

青蒿鲨烯合酶基因的克隆、结构分析与大肠杆菌表达

用RT-PCR方法从青蒿(Artemisia annua L.)中克隆了一个1 539 bp全长鲨烯合酶cDNA.青蒿鲨烯合酶氨基酸序列与拟南芥、烟草、人类、酵母鲨烯合酶的一致性分别为70%、77%、44%和39%.青蒿鲨烯合酶基因组DNA结构很复杂,包括14个外显子和13个内含子.全长的或C末端截短的鲨烯合酶cDNA被克隆进原核表达载体pET30a并在大肠杆菌(Escherichia coli) BL21(DE3)中诱导表达.但在含有全长的鲨烯合酶cDNA的大肠杆菌中并没有观察到预期大小的鲨烯合酶表达,而C末端截短疏水区30个氨基酸的鲨烯合酶可在大肠杆菌中过量表达.     

人G—CSF基因组基因的克隆及其在转基因小鼠乳腺表达的研究

采用ＰＣＲ方法以正常中国人脐带血提取总ＤＮＡ为模板,扩增出１．５Ｋｂ的粒细胞集落刺激因子（Ｇ－ＣＳＦ）基因组基因,序列分析证实其正确性,将其插入小鼠乳清酸蛋白（ＷＡＰ）基因的起支密码子ＡＴＧ臆的ＫｐｎＩ位点,使其受控于２．６ｋｂ的ＷＡＰ调控序列,从而构建乳腺表达载体ｐＷＧＧ。回收经ＥｃｏＲＩ酶切后的８．７ｋｂ片段用于显微注射,共注射１２００枚受精卵,移植至受体３４母鼠,产生仔鼠８５只,经ＰＣＲ检测     

The Human Hepatocyte Nuclear Factor 3/Fork Head Gene FKHL13: Genomic Structure and Pattern of Expression

We describe the isolation and characterization of the cDNA for FKHL13, the human homologue of the mouse hepatocyte nuclear factor 3/fork headhomologue 4 (HFH-4) gene, a member of the HNF-3/fork head(also called winged helix) gene family. Members of this gene family contain a conserved DNA binding region of approx. 110 amino acids and are thought to play an important role in cell-specific differentiation. Previous analysis of the mouse and rat HFH-4 cDNAs revealed a distinct pattern of expression for this gene, suggesting that the gene plays an important role in the differentiation of lung and oviduct/ampulla epithelial cells and testicular spermatids. Analysis of the human FKHL13 gene confirmed this pattern of expression. We also found expression in adult human brain cortex, which we were able to confirm for the mouse. The expression pattern of FKHL13/HFH-4, confined to cilia/flagella-producing cells, leads us to believe that the gene plays an important role in the regulation of axonemal structural proteins. We show that the human gene for FKHL13 lies on chromosome 17 (comparison with the chromosomal location of the mouse gene strongly suggests 17q22–q25) and that the gene, which is approx. 6 kb, contains a single intron disrupting thefork headDNA binding domain. Such a disruption of a functional unit provides strong evidence for the theory of intron insertion during gene evolution. The expression of the gene is probably controlled by the CpG island, which is located in the promoter region of the gene. We also demonstrate that the FKHL13 gene is highly conserved among a wide variety of species, including birds.     

Human Microtubule-Associated Protein 1a (MAP1A) Gene: Genomic Organization, cDNA Sequence, and Developmental- and Tissue-Specific Expression

Microtubule-associated proteins (MAPs) regulate microtubule stability and play critical roles in neuronal development and the balance between neuronal plasticity and rigidity. MAP1a (HGMW-approved symbol MAP1A) stabilizes microtubules in postnatal axons. We describe human MAP1a's genomic organization and deduced cDNA and amino acid sequences. MAP1a is a single-copy gene spanning 10.5 kb. MAP1a coding sequence is contained in five exons. Translation begins in exon 3. Human MAP1a contains 2805 amino acids (predicted molecular weight 306.5 kDa) and is slightly larger than rat MAP1a (2774 amino acids). Like rat and bovine MAP1a, human MAP1a contains conserved tubulin binding motifs in the amino-terminal region. The carboxy-terminal portion contains a conserved pentadecapeptide that is present in the light chain portion of rat and bovine MAP1a/LC2 polyprotein. We show that human MAP1a gene expression occurs almost exclusively in the brain and that there is approximately 10-fold greater gene expression in adult brain compared to fetal brain. Strong, interspecies conservation between human and rat MAP1a cDNA and amino acid sequences indicates important relationships between MAP1a's function and its primary amino acid sequence.