巴西橡胶树(Hevea brasiliensis)微管相关蛋白全长cDNA克隆及表达分析

从巴西橡胶树Hevea brasiliensis差减cDNA文库中分离到微管相关蛋白（Microtubule-associated protein,MAPs）基因片段,根据该基因片段序列信息,设计特异引物,采用cDNA末端快速扩增技术RACE（Rapid Amplification ofcDNA Ends）进行差异片段的5＇和3＇端的扩增,获得了长度为788bp的全长cDNA,该基因在GenBank中的登录号为AY461412.序列分析表明该基因包含完整的开放阅读框,编码144个氨基酸,与微管相关蛋白基因家族具有很高的同源性,推测该基因是微管相关蛋白基因.半定量RT-PCR检测证实它在胶乳中的表达强于叶中,胁迫处理（伤害及乙烯处理）使其表达上调.     

t-PA cDNA在CHO细胞中的高效稳定表达

我们曾报道t-PA mRNA非翻译区序列对其表达有明显的抑制作用,在此基础上,通过对5′-UTR及3′-UTR的改造,使t-PA在COS-7细胞中的表达水平提高30倍左右。将t-PA表达质粒用电击法转染中国仓鼠卵巢细胞二氢叶酸还原酶缺陷株(CHO-dhfr),经过混合加压及筛选,在CHO细胞中高效表达了t-PA,表达水平达到5000～6000 IU/10~6细胞/24hr。重组t-PA具有与天然t-PA相同的分子量及酶活性。经过8个月连续传代,表达水平未下降,表明细胞株是稳定的,其主要指标均符合工程细胞株的要求。     

Expression of the two nested overlapping reading frames of turnip yellow mosaic virus RNA is enhanced by a 5' cap and by 5' and 3' viral sequences

The translation efficiency of an mRNA molecule is typically determined by its 5'- and/or 3'-untranslated regions (UTRs). Previously, we have found that the 3'-UTR of Turnip yellow mosaic virus (TYMV) RNA enhances translation synergistically with a 5' cap. Here, we use a luciferase reporter system in cowpea protoplasts to show that the 5' 217 nucleotides from TYMV genomic RNA enhance expression relative to a vector-derived 17-nucleotide 5'-UTR. Maximum expression was observed from RNAs with a cap and both 5' and 3' TYMV sequences. In paired reporter constructs, the 5' 217 nucleotides harboring the UTR and the first 43 or 41 codons of the two overlapping TYMV open reading frames (ORFs), ORF-69 and ORF-206, respectively, were fused in frame with the luciferase gene. This allowed expression from the initiation codon of each ORF (AUG69 and AUG206) to be monitored separately but from the normal sequence environment. Expression from both AUG codons was heavily dependent on a 5' cap, with a threefold-higher expression occurring from AUG69 than from AUG206 in the presence of the genomic 3'-UTR. Changes that interrupted the cap/3'-UTR synergy (i.e., removal of the cap or TYMV 3'-UTR) resulted in a higher proportion of initiation from AUG206. Mutation of the 3'-UTR to prevent aminoacylation, as well as deletion of 75% of the 5'-UTR, likewise resulted in a lower ratio of expression from AUG69 relative to AUG206. Mutation of each AUG initiation codon increased initiation from the other. Taken together, these results do not fully conform to the expectations of standard leaky ribosomal scanning and leave open the precise mechanism of ribosome commitment to AUG69 and AUG206. However, our observations do not support a recent proposal based on in vitro studies in which the 3'-UTR is proposed to direct cap-independent initiation specifically at AUG206 and not at AUG69 (S. Barends et al., Cell 112:123-129, 2003).     

Conserved repressive regulation of connective tissue growth factor/hypertrophic chondrocyte-specific gene 24 (ctgf/hcs24) enabled by different elements and factors among vertebrate species

CTGF/Hcs24 is a multifunctional growth factor that potentiates the growth and differentiation of various cells. Our previous study revealed that the 3'-UTR of mammalian CTGF/Hcs24 mRNA contains a small segment that represses the gene expression in cis fashion. In this study, we isolated and characterized a chicken CTGF/Hcs24 cDNA clone. Chicken ctgf/hcs24 mRNA showed highly conserved homology in the ORF to that of mammalian species, whereas the homology in the 3'-UTR was relatively low. Northern blotting analysis revealed that chicken ctgf/hcs24 mRNA was expressed most strongly in cartilage, and also in brain, lung, heart, but faintly in liver. Thereafter we analyzed the functional potential of the 3'-UTR of ctgf/hcs24 cDNA to regulate its gene expression by reporter gene assay, and found that it repressed gene expression in cis fashion, specifically in avian cells, but not in mammalian cells. Conversely, the mammalian 3'-UTR showed less repressive activity in avian cells than in mammalian cells. Deletion analysis showed that a segment near the polyadenyl tail of the 3'-UTR of chicken ctgf/hcs24 played an important functional role, unlike in the mammalian species. Thus, we uncovered a novel mode of functional conservation of the ctgf/hcs24 3'-UTR among vertebrate species mediated by different factors.     

Chicken transferrin receptor gene: conservation 3'' noncoding sequences and expression in erythroid cells.

Recombinant clones of the chicken transferrin receptor gene and cDNA have been isolated and sequenced. Two highly conserved regions have been identified in the 3' noncoding sequence of the human and chicken TR gene. The conserved regions include sequences that have been shown to be involved in the iron-dependent regulation of human TR mRNA stability. These sequences can be modeled as two different types of RNA secondary structures, one containing stem-loop structures that are similar to the iron-responsive elements found in ferritin mRNA and the other being a stable, duplex/stem-loop structure. Both forms show considerable similarity between chicken and human mRNA. The expression of TR is developmentally regulated during erythroid maturation, and immature erythroid cells express exceptionally high levels of TR mRNA.     

Specific protein binding to a conserved region of the ornithine decarboxylase mRNA 5'-untranslated region.

An RNA gel retardation assay was used to identify one or more cellular protein(s) (ornithine decarboxylase mRNA 5'-UTR binding protein (ODCBP)) that bind specifically to a conserved region of the 5'-untranslated region (5'-UTR) of rat ornithine decarboxylase (ODC) mRNA. Ultraviolet light cross-linking demonstrated that this protein has an apparent Mr = 58,000 in mammalian cells. Treatment with the oxidizing agent diamide prevented binding of the ODCBP to ODC mRNA; addition of beta-mercaptoethanol reversed this inhibition and permitted mRNA.ODCBP complex formation. Cytoplasmic extracts from a variety of animal cells and tissues demonstrated similar binding activities; however, there was marked tissue-specific expression of the protein in the rat, with brain, heart, lung, and testis containing large amounts, and kidney, spleen, and skeletal muscle expressing negligible amounts. Binding was completely prevented by several mutations within a highly conserved heptanucleotide region (CCAU/ACUC) that was within 61 bases of the initiation codon in ODC mRNAs from mammals, Xenopus, and Caenorhabditis elegans; mutations 5' and 3' of the conserved heptanucleotide domain had no effect on binding activity. Binding was not affected by manipulation of cellular polyamine levels or by treatment of cells with agents that stimulate ODC biosynthesis. Thus, we have identified a widely distributed cellular protein that binds to a conserved domain within the 5'-UTR of ODC mRNA from many animal species; functional consequences of this binding remain to be determined.