The prokaryotic neomycin-resistance-encoding gene acts as a transcriptional silencer in eukaryotic cells

The gene encoding neomycin resistance (neo) mediates a cis-acting negative effect on expression from promoters in transient and stable transfectants of mammalian cell lines. Inserting the neo gene either into retroviral vectors or into plasmids containing reporter genes results in a five- to tenfold decrease of expression from proximal promoters like the simian virus 40 early or the retroviral myeloproliferative sarcoma virus promoter. The silencing effect is not dependent on the insertion site or the orientation of the fragment. The neo gene is frequently used in eukaryotic vectors as a dominant selectable gene. Other selectable genes were tested for potential cis-activity. We found that the gene conferring resistance to puromycin from Streptomyces alboniger does not influence adjacent promoters.     

牙鲆钙调素基因在原核和真核细胞中的表达

设计特异引物,以SMART cDNA为模板,应用PCR方法扩增牙鲆钙调素基因（Paralichthys olivocew calmodulin,PoCaM）。计算机辅助分析表明,PoCaM基因编码149个氨基酸的推定蛋白,其分子量为17kD,等电点为3．93,含有4个螺旋-环-螺旋样结构,与其它鱼类CaM氨基酸一致性为97．3％-100％。构建原核表达重组质粒pET32a／PoCaM,转化大肠杆菌B121（DE3）,用IPTG进行诱导表达,经SDS—PAGE蛋白电泳,结果显示PoCaM在大肠杆菌中进行了特异性融合表达,融合蛋白分子量约为34kD,与预期分子量大小一致。同时,以绿色荧光蛋白（GFP）为表达标签,构建真核表达重组质粒pEGFP—N3／PoCaM,经Lipofectamine 2000介导转染鲤鱼上皮瘤细胞（ Epithelioma papulosum cyprinid, EPC）,荧光显微镜观察显示,PoCaM在EPC细胞中进行瞬时表达,主要分布于细胞核及胞浆中[动物学报54（6）：1061—1067,2008]。     

Glucanase gene diversity in prokaryotic and eukaryotic organisms

A number of bacteria and eukaryotes produce extracellular enzymes that degrade various types of polysaccharides including the glucans starch, cellulose and hemicellulose (xylan). The similarities in the modes of expression and specificity of enzyme classes, such as amylase, cellulose and xylanase, suggest common genetic origins for particular activities. Our determination of the extent of similarity between these glucanases suggests that such data may be of very limited use in describing the early evolution of these proteins. The great diversity of these proteins does allow identification of their most highly conserved (and presumably functionally important) regions.     

Construction of a neo fusion gene for expression in both prokaryotic and eukaryotic cells

A high-copy-number plasmid, pLink, was constructed to allow the direct selection in Escherichia coli of a neo fusion gene capable of conferring Geneticin (G418) resistance on mouse L cells. pLink was derived from pdMmtneo by insertion of a KpnI linker within the 5'-coding region of the neo gene. This created a minus-one frameshift mutation resulting in a translational termination within the N-terminal region of the protein. The Neo activity was restored by insertion into the modified neo gene of a piece of coding sequence derived from human HPRT cDNA. The resulting plasmid, pAH, was microinjected into mouse A9 cells and shown to confer resistance to G418.     

Pathways of arsenic uptake in prokaryotic and eukaryotic cells

Mechanisms of arsenic uptake and detoxification are present in all studied organisms. These mechanisms are considerably well described in unicellular organisms such as bacterium Escherichia coli and baker's yeast Saccharomyces cerevisiae, still leaving much to be revealed in multicellular organisms. Full identification of arsenic uptake and detoxification is of great importance. This knowledge can be very helpful in improving effectiveness of arsenic-containing drugs used in chemotherapy of parasitoses as well as in treatment of acute promielyocytic leukemia. Increased proficiency of bioremediation of arsenic-contaminated soils can be obtained by using plants hyperaccumulating arsenic. This kind of plants can be engineered by modulating expression levels of genes encoding arsenic transporters. The same technique may be used to decrease levels of accumulated arsenic in crops. The aim of this paper is to review current knowledge about systems of arsenic uptake in every studied organism--from bacteria to human.     

The L-type calcium channel alpha 1C subunit gene undergoes extensive, uncoordinated alternative splicing

The alpha1C subunit is the pore-forming protein for the L-type calcium channel. Previous studies indicate that there is possible tissue-specific alternative splicing of this gene. In this study we cloned the entire open reading frame of the alpha1C subunit cDNA from adult rat cardiac myocytes in a single piece (6.64 kb). Using 75 positive clones that were identified by restriction enzyme mapping, we tested the alternative splicing patterns of the Ca(v) 1.2 gene that encodes the alpha1C subunit protein and focused on five loci: IS6, post-IS6, IIIS2, IVS3, and the c-terminus. The results indicate that: (1) alternative splicing occurs in most of the loci, giving rise to two or three different isoforms at those sites; (2) there is a predominant form for each splicing site, (3) there does not appear to be consistent coordination of splicing at multiple loci of this gene. Alternative splicing is not tissue-specific in most regions.     

The L-type calcium channel alpha 1C subunit gene undergoes extensive,uncoordinated alternative splicing

The _1C subunit is the pore-forming protein for the L-type calcium channel. Previous studies indicate that there is possible tissue-specific alternative splicing of this gene. In this study we cloned the entire open reading frame of the _1C subunit cDNA from adult rat cardiac myocytes in a single piece (6.64 kb). Using 75 positive clones that were identified by restriction enzyme mapping, we tested the alternative splicing patterns of the Ca_v1.2 gene that encodes the _1C subunit protein and focused on five loci: IS6, post-IS6, IIIS2, IVS3, and the c-terminus. The results indicate that: (1) alternative splicing occurs in most of the loci, giving rise to two or three different isoforms at those sites; (2) there is a predominant form for each splicing site, (3) there does not appear to be consistent coordination of splicing at multiple loci of this gene. Alternative splicing is not tissue-specific in most regions. (Mol Cell Biochem 269: 153–163, 2005)     

Glycosylation and post-translational modification gene expression analysis by DNA microarrays for cultured mammalian cells

DNA microarray analysis of gene expression has become a valuable tool for bioprocessing research aimed at improving therapeutic protein yields. The highly parallel nature of DNA microarray technology allows researchers to assess hundreds of gene simultaneously, essentially enabling genome-wide snapshots. The quality and amount of therapeutic proteins produced by cultured mammalian cells rely heavily on the culture environment. In order to implement beneficial changes to the culture environment, a better understanding of the relationship between the product quality and culture environment must be developed. By analyzing gene expression levels under various environmental conditions, light can be shed on the underlying mechanisms. This paper describes a method for evaluating gene expression changes for cultured NS0 cells, a mouse-derived myeloma cell line, under culture environment conditions, such as ammonia buildup, known to affect product quality. These procedures can be easily adapted to other environmental conditions and any mammalian cell lines cultured in suspension, so long as a sufficient number of gene sequences are publicly available.     

Active site residues of cephalosporin acylase are critical not only for enzymatic catalysis but also for post-translational modification

Cephalosporin acylase (CA) is a recently identified N-terminal hydrolase. It is also a commercially important enzyme in producing 7-aminocephalosporanic acid (7-ACA), a backbone chemical in synthesizing semi-synthetic cephalosporin antibiotics. CA is translated as an inactive single chain precursor, being post-translationally modified into an active enzyme. The post-translational modification takes place in two steps. The first intramolecular autocatalytic proteolysis takes place at one end of the spacer peptide by a nucleophilic Ser or Thr, which in turn becomes a new N-terminal Ser or Thr. The second intermolecular modification cleaves off the other end of the spacer peptide by another CA. Two binary structures in complex with glutaryl-7-ACA (the most favored substrate of CAs) and glutarate (side chain of glutaryl-7-ACA) were determined, and they revealed the detailed interactions of glutaryl-7-ACA with the active site residues (Y. Kim and W. G. J. Hol (2001) Chem. Biol., in press). In this report: 1) we have mutated key active site residues into nonfunctional amino acids, and their roles in catalysis were further analyzed; 2) we performed mutagenesis studies indicating that secondary intermolecular modification is carried out in the same active site where deacylation reaction of CA occurs; and 3) the cleavage site of secondary intermolecular modification by another CA was identified in the spacer peptide using mutational analysis. Finally, a schematic model for intermolecular cleavage of CA is proposed.     

Non-mutagenic and mutagenic post-replicative DNA repair in prokaryotic and eukaryotic cells

The review is devoted to mechanisms of repair gaps in DNA daughter strand, formed during the stall of moving replication forks and restart of replication in cells after the action of DNA damaging agents (predominantly--UV light). The repair of daughter DNA, or postreplication DNA repair (PRR), is realized by error-free (non-mutagenic) and error-prone (mutagenic) pathways. The former is a recombination repair, or recombination between two sister duplexes. By this way the major part of postreplication gaps is eliminated. The second way is related with the induction of SOS-response. In Escherichia coli cells mutagenic SOS-response is realized by proteins RecA, UmuD, UmuC, DNA-polymerase III holoenzyme and others. In E. coli some mutagenic enzymes--DNA-polymerase IV (the product of dinB gene) and DNA-polymerase V (the product of umuDC genes) have been recently discovered. In Saccharomyces cerevisiae cells postreplicative translesion synthesis is realized by newly discovered enzymes deoxycytidilmonophosphatetransferase (encoded by REV1 gene), DNA-polymerase zeta (encoded by REV3 gene), DNA-polymerase eta (encoded by RAD30 gene). All the three enzymes share a great homology with UmuC enzyme of E. coli. DNA polymerase eta correctly inserts adenine residues in the daughter strand opposite noncoded thymine residues in cyclobutane pyrimidine dimer. Based on RAD6 gene of S. cerevisiae, human cells hREV1, hREV3 and hRAD30A have been obtained to encode, respectively, deoxycytidiltransferase, DNA-polymerase zeta and DNA-polymerase eta. It has been shown that the defect of PRR DNA in xeroderma pigmentosum variant is associated with DNA-polymerase eta deficiency. This defect is corrected by the extract of intact HeLa cells. The importance of newly discovered enzymes in the system of mechanisms of DNA repair and replication is discussed.     

The origin of eukaryotes: the difference between prokaryotic and eukaryotic cells.

Eukaryotes have long been thought to have arisen by evolving a nucleus, endomembrane, and cytoskeleton. In contrast, it was recently proposed that the first complex cells, which were actually proto-eukaryotes, arose simultaneously with the acquisition of mitochondria. This so-called symbiotic association hypothesis states that eukaryotes emerged when some ancient anaerobic archaebacteria (hosts) engulfed respiring alpha-proteobacteria (symbionts), which evolved into the first energy-producing organelles. Therefore, the intracellular compartmentalization of the energy-converting metabolism that was bound originally to the plasma membrane appears to be the key innovation towards eukaryotic genome and cellular organization. The novel energy metabolism made it possible for the nucleotide synthetic apparatus of cells to be no longer limited by subsaturation with substrates and catalytic components. As a consequence, a considerable increase has occurred in the size and complexity of eukaryotic genomes, providing the genetic basis for most of the further evolutionary changes in cellular complexity. On the other hand, the active uptake of exogenous DNA, which is general in bacteria, was no longer essential in the genome organization of eukaryotes. The mitochondrion-driven scenario for the first eukaryotes explains the chimera-like composition of eukaryotic genomes as well as the metabolic and cellular organization of eukaryotes.     

Transfer and expression of plasmids containing human cytomegalovirus immediate-early gene 1 promoter-enhancer sequences in eukaryotic and prokaryotic cells

The human cytomegalovirus immediate-early gene region 1 promoter-enhancer is active in bacteria and in many mammalian cells. Recombinant plasmids containing portions of this DNA can be used to promote the expression of foreign proteins in many cells. In this communication, we report the optimal conditions for transfer of plasmid DNA to cells by electroporation and the transient expression assays which document the activity of different promoter constructions. The observed activity of the human cytomegalovirus promoter is more than 100-fold higher than the activity of the early promoter of SV40.     

A thermostable Clostridium thermocellum lichenase-based reporter system for studying the gene expression regulation in prokaryotic and eukaryotic cells

A new reporter system was developed to study the gene expression regulation in prokaryotic (Escherichia coli) and eukaryotic (Saccharomyces cerevisiae and mammalian) cells. The system was based on the modified bacterial lichenase gene (licBM2), which was shown to meet the requirements for a reporter. The gene product was active and did not undergo modification in heterologous hosts. Simple and sensitive methods were used to detect and to quantitate the lichenase activity. Inducible licBM2 expression was demonstrated with E. coli and yeast cells, allowing the system to be employed in dynamic studies.     

A universal strategy for regulating mRNA translation in prokaryotic and eukaryotic cells

We describe a simple strategy to control mRNA translation in both prokaryotic and eukaryotic cells which relies on a unique protein–RNA interaction. Specifically, we used the Pumilio/FBF (PUF) protein to repress translation by binding in between the ribosome binding site (RBS) and the start codon (in Escherichia coli), or by binding to the 5′ untranslated region of target mRNAs (in mammalian cells). The design principle is straightforward, the extent of translational repression can be tuned and the regulator is genetically encoded, enabling the construction of artificial signal cascades. We demonstrate that this approach can also be used to regulate polycistronic mRNAs; such regulation has rarely been achieved in previous reports. Since the regulator used in this study is a modular RNA-binding protein, which can be engineered to target different 8-nucleotide RNA sequences, our strategy could be used in the future to target endogenous mRNAs for regulating metabolic flows and signaling pathways in both prokaryotic and eukaryotic cells.     

Bifunctional reporter genes: construction and expression in prokaryotic and eukaryotic cells

Bifunctional reporter proteins were constructed to combine Clostridium thermocellum lichenase (LicBM2) with Aequorea victoria green fluorescent protein (GFP) or with Escherichia coli beta-glucuronidase (GUS). The major properties of the initial proteins were preserved in the hybrid ones: LicBM2 was active at 65 degrees C, GFP fluoresced, and GUS hydrolyzed its substrates. LicBM2 remained active after extension of its C of N end. Bifunctional reporter systems were shown to provide a convenient tool for studying the gene expression regulation in prokaryotic (E. coli) and eukaryotic (Saccharomyces cerevisiae, mammalian) cells, advantages of one reporter compensating for drawbacks of the other.     

组蛋白翻译后修饰技术研究进展

翻译后修饰调控着真核生物大部分蛋白质的活性,这些修饰的解读对研究生物功能是必不可少的。组蛋白翻译后修饰是蛋白质翻译后修饰中研究的较好一类小分子碱性蛋白,易被各种生物大分子修饰,尤其易发生在N-末端的尾部。不同组合式修饰构成了"组蛋白密码",在细胞的发育、生长、分化和动态平衡中,组蛋白密码影响着染色体的结构状态,进而调控基因的表达状态。组蛋白翻译后修饰的研究可作为一种模式来解析蛋白质复杂的修饰状态及研究其分子功能。翻译后修饰分析技术的发展对组蛋白密码的解析是至关重要的。重点讨论组蛋白修饰分析技术的发展和应用。